ART, MATHEMATICS AND MUSIC

 

 

Benno Moiseiwitsch

 

 

 

CONTENTS

 

Preface

 

Introduction

 

1. Primitive Art

 

2. Music

 

3. Islamic Art

 

4. Renaissance Art

 

5. Modern Art

 

6. Epilogue

 

Appendix A. Golden Section

Appendix B. Spiral Curves

Appendix C. Mandelbrot Sets

 

References

 

 

 

Moonlight Sonata

 

PREFACE

 

 

The main idea behind the writing of this article was to establish that art, mathematics and music, as well as science and astronomy, are in many ways quite closely connected together.

 

The drawing and painting of people and animals, an activity of artists since primitive times, is clearly associated with symmetry, and thus geometry, since the human form and the forms of living creatures in general are obviously highly symmetrical in shape. Indeed the beauty of the human form, and also of an animal such as the horse, is firmly based on their symmetrical proportions. Thus artists such as Leonardo da Vinci and Albrecht Dürer were deeply concerned with the proportions of the human form from a truly geometrical point of view.

 

Further, sculpture and architecture have a strongly geometrical basis as is evident from the wonderful work of the Italian Renaissance men Brunelleschi, Alberti and Michelangelo.

 

The geometry of perspective used by the Renaissance artists and subsequently by many artists in later times has been subjected to detailed analysis by several authors, for example in the book by Kemp¹ devoted to optical themes in western art.

 

The repeating patterns and designs used in Islamic art are strongly based on the geometry of the fundamental regular polygons such as the triangle, square, pentagon, hexagon, octagon and so on, up to polygons with 24 sides, and also on other beautiful geometrical shapes.

 

The subject of astronomy has always been dependent to a great extent on geometry. Johannes Kepler, the astronomer who discovered that the planets move round the sun in ellipses, was greatly interested in the subject of geometry. He examined how a plane could be completely filled with equal regular polygons such as the equilateral triangle, the square and the hexagon with six equal sides, and also studied the subject of polyhedra or convex solid bodies with flat faces.

 

In 1985 an International Congress on M. C. Escher was held in Rome. The graphic work of Escher has been of profound interest to many mathematicians for a considerable time and has led to many kinds of mathematical challenges, geometrical investigations and research². His work was much influenced by the repeating patterns used by the Islamic artists of Granada in Spain.

 

Escher was able to use the symmetrical shapes of living creatures such as birds, fishes and insects of various kinds as well as flowers to create his wonderful periodic patterns. In this context it is well worth recollecting that scientifically minded people believe that the shapes of all living creatures and vegetation, including plants and trees, have come about by the action of Darwinian evolution arising from their successful adaptation to the ambient environment in which they flourished over long periods of time often leading to their beautiful symmetry and consequently their use as models for human art. Thus we could say that art is founded, at least in part, on the past history of life on Earth.

 

Music and mathematics also have a close affinity as is readily apparent from the two books of 24 Preludes and Fugues composed by Johann Sebastian Bach using the equal-temperament scale, also known as the well-tempered Clavier. One remembers that Pythagoras did fundamental work on the foundations of the musical scale and on the vibrations of strings, and that the French mathematician Mersenne was also a musician and was the originator of the equal-temperament scale.

 

Artists have frequently shown a great affinity with music and their pictures often include singers, musicians as well as musical instruments. The modern artist Wassily Kandinsky originally wished to be a musician and another artist of the same generation Paul Klee was a talented violinist throughout his life.

 

For all these diverse reasons it is highly interesting as well as instructive and revealing to investigate the relationship between art, music and mathematics in its various aspects, and this is what I have tried to do in this article employing just elementary geometry and algebra. It arose originally from a lecture that I gave on Mathematics and Art at the British Association for the Advancement of Science meeting held in Belfast in August 1987. More recently, in 1999, I gave a lecture on the same subject in a somewhat modified form at a meeting of the Belfast Branch of the Institute of Mathematics and its Applications which was subsequently published in a considerably revised and abbreviated form as an article in Mathematics Today, the Bulletin of the IMA³.

 

To those who have a deeper interest in the mathematics involved in this article, I have left the more advanced mathematical discussion to the Appendices.

 

I have found many books very useful in the preparation of this article. In particular I wish to acknowledge the importance of the book by Martin Kemp¹ on the Science of Art, the volume on the art of M. C. Escher edited by H. S. M. Coxeter, M. Emmer, R. Penrose and M.L. Teuber², the books by Dorothy K. Washburn and Donald W. Crowe⁵ on the Symmetries of Culture, Sir James Jeans⁹ on Science and Music, D'Arcy Thompson¹¹ on Growth and Form, Keith Critchlow¹² on Islamic Patterns, Marilyn Aronberg Lavin²³ on Piero della Francesca, Caroline H. Macgillavry²⁵ on the Symmetry Aspects of M. C. Escher's Periodic Drawings, and the article by Martin Gardener²⁷ on Roger Penrose's nonperiodic tessellations.

 

 

INTRODUCTION

 

 

In the following I shall carry out an exploration of the nature of the relationship between art, mathematics and music. Since true art as well as music has meaning and significance, it must necessarily have pattern and structure and so one would expect that it should therefore possess, at least to some extent, a character based on symmetry, geometry, and even mathematics in certain examples.

 

Although the art of early cultures is often referred to as being primitive this by no means implies that it was not highly significant and without great merit. Indeed the cave artwork dating from many tens of thousands of years ago found in Spain and France is very attractive and revealing as well as exhibiting a close affinity with nature. It shows that primitive people were highly artistic and not inferior to ourselves in mental capacity but simply limited by the tools and pigments that were available for them to use in those days.

 

Stone age artists carved interesting geometrical designs such as spirals on the large stones in their passage-graves like that found at Newgrange in Ireland. The significance of these spirals is not entirely clear but is very likely associated with the seasonal decline and subsequent rise of the Sun since in the case of Newgrange the Sun shines directly down the stone passage way precisely at the winter solstice when the day is shortest and, for a few minutes, lights up the grave chamber which is normally in utter darkness. Thus spirals are associated with the Sun and its very regular periodic motion, and may be a symbol for the life cycle as well as resurrection and a belief in the possibility of immortality for the high ranking people buried in the tomb since at the winter solstice the day is about to increase in length and heralds the rebirth of the Sun and the coming of spring.

 

The massive stones from which this passage grave was built were assembled so accurately that it has survived for thousands of years without significant movement and testifies to the mathematical understanding of the stresses and strains in the megalithic construction by the Neolithic engineers who designed it.

 

Similar passage graves are found elsewhere, for example to the north of Scotland in the Orkney Islands at Maeshowe a few miles away from Skarabrae on the Mainland of Orkney, and at Midhowe on Rousay Island.

 

Spirals were also used to decorate the beautiful ceramic pots made by the native American people who lived about a 1000 years ago in the lost city known as Cahokia in Missouri. This city also possessed many tumuli in which people of a high status were buried. The modern day Choctaw Indians, who continue to use spirals for decoration, may be connected with the people of Cahokia.

 

It is well understood that some primitive art was strongly influenced by considerations of symmetry⁴. Indeed Washburn and Crowe⁵ have pointed out that the various cultures spread around the world have such marked preferences for particular types of symmetry that their works of art can be identified by their choice of symmetry classes. The patterns used by the ancient Egyptian artists as long ago as 1300 B.C. and earlier demonstrate that they had a fair appreciation of the geometry involved in their use of symmetry. Nevertheless their geometry was rather primitive as can be seen from the fact that they calculated the area of a circle having diameter d using the rule A = (8d/9)² which is equivalent to taking p to be 256/81 = 3.16... rather than the better approximation 22/7 = 3.14... used by the ancient Greeks and even today for approximate work. Regular polygons with 24 sides were used by the ancient Egyptians in the decoration of tombs which may be associated with the fact that they divided the day into 24 hours and moreover that the number 24 is exactly divisible by as many as six numbers, namely the prime numbers 2, 3 as well as the composite numbers 4, 6, 8, 12.

 

Simple geometrical figures such as spirals were used to decorate Mycenaean Greek jars as early as the fifteenth century B.C. and later arcs and circles were used by the Greeks to decorate amphora or storage vessels, and kraters or two handled jars for mixing wine with water, in the tenth century B.C. known as the Protogeometric period. Then more elaborate geometrical patterns such as meanders, zigzags and triangles as well as animal and human figures were used to decorate kraters in the ninth and eighth centuries B.C. in the full Geometric period⁶.

 

The nature and behaviour of the Sun and all the other heavenly bodies have always produced wonderment in human beings. It is fascinating that the ancient Greek Aristotelian interpretation of the motions of the Sun, the Moon, the wandering planets, namely Mercury, Venus, Mars, Jupiter and Saturn, and the fixed stars, by means of rotating crystalline spheres centred at the fixed Earth, was called the music of the spheres by the Greek mathematician Pythagoras (c. 380-300 B.C.).

 

The motions of the planets were given complicated but fairly accurate, although not perfect, descriptions by the Greek mathematician and astronomer Ptolemy (c. 150 A.D.) making use of epicycles, that is paths traced out by points which move on the circumferences of circles whose centres move on the circumferences of other larger circles centred at the Earth (see Appendix B and Fig. 9). This was done, in particular, to take account of the observed retrograde motions of the planets in the night sky and thus avoid centering their motions around the Sun although this had been known to simplify the interpretation of planetary motions by Aristarchus (c. 281 B.C.)⁷. However it remained difficult for most people at that time to believe that the Earth moved and was not the centre of the universe.

 

Johannes Kepler (1571-1630), the astronomer who discovered that the orbital paths of the planets round the sun are ellipses, one of the conic sections which are curves produced by cutting a cone with a plane, was deeply interested in spatial relationships. He examined how a plane could be completely filled with congruent regular polygons and also wrote on the subject of the convex solid bodies with flat faces known as polyhedra. He first thought that the orbits of the planets Saturn, Jupiter, Mars, the Earth and Venus were circles which could be fitted between the regular polygons, namely an equilateral triangle, a square, a regular pentagon, a regular hexagon, and so on. He found that this simple geometrical structure failed but later on, in his treatise Mysterium Cosmographicum, he attempted to place the orbits of the planets on spheres which were fitted between the regular Platonic solids: that is the tetrahedron with four faces, the cube with six faces, the octahedron with eight faces, the dodecahedron with twelve faces and the icosahedron with twenty faces, which he eventually realized was also not a feasible solution. He next decided that the orbit of Mars, determined from the observations of the astronomer Tycho Brahe (1546-1601), was an oval having an egg-like shape before eventually realizing, as if he had been awakened from a sleep, that it was an ellipse as he explains in his book Astronomia Nova, aptly named the New Astronomy. An illuminating description of the way in which Johannes Kepler and those astronomers who preceded him, like Nicolas Copernicus (1473-1543) and Tycho Brahe, tried to understand the motions of the planets is given in the book The Sleepwalkers by Arthur Koestler⁸.

 

The Pythagoreans, believed that all natural phenomena, including the motions of the planets already mentioned, are derived from harmony based on numbers. The sounds produced by a vibrating string or a pipe were placed on a mathematical basis by Pythagoras, who made the assumption that the notes should be separated by well-defined regular intervals such as the frequency ratio  corresponding to the dominant note G which is a fifth above the first note C or tonic of an octave. This idea was further developed by other mathematicians and musicians such as the French philosopher and theologian Mersenne (1588-1648) who devised the equal-temperament scale that was used by Johann Sebastian Bach (1685-1750) in his two books of 24 Preludes and Fugues, das wohltemperierte Klavier or the well-tempered Clavier, and by other composers of music⁹.

 

Obviously there is a fundamental property that differentiates music from pictorial art. Thus music is a form of art that is founded on the steady forward progression of time, like the motions of the planets and the diurnal motion of the heavens, whereas painting, drawing, sculpture and architecture are all static art forms. However one recollects that Degas (1834-1917) once said that his chief interest in dancers was in rendering movement, and the surrealist painter Paul Klee (1879-1940) remarked that: 'Pictorial art springs from movement, is itself fixed movement, and is perceived through movements'. It is instructive to remember that Paul Klee was a talented amateur violinist and that another modern artist Wassily Kandinsky (1866-1944) originally wished to be a musician. Artists have frequently introduced musicians and musical instruments into their artwork. For example Pablo Picasso (1881-1973) painted pictures having the titles Man with a Guitar and The Three Musicians.²⁹ The watercolour Moonlight Sonata by the artist Daniel Moiseiwitsch (1919-1944) given in the frontispiece of this article also represents a picture with a musical connection: it shows a grand piano seen through a window with the music displayed of Beethoven’s Moonlight sonata in C sharp minor.

 

The relationship between mathematics, science, music and art has been of great interest for a long time. Indeed the mathematical sciences part of the medieval liberal arts course known as the quadrivium comprised the four subjects of arithmetic, geometry, astronomy and music. Further the great interest in these subjects is made evident from the painting by Hans Holbein the Younger (1497/8-1543) known as The Ambassadors, to be seen in the National Gallery London, which depicts astronomical and musical instruments, a peculiar mathematical distortion of a skull which can be corrected by viewing from the far right or by using a glass cylinder placed on a photograph of the painting, as well as the portraits of the two diplomats.

 

The golden section ratio (1+Ö5)/2 = 1.61803... or its alternative reciprocal form (-1+Ö5)/2 = 2/(1+Ö5) = 0.61803... in the geometry of Pythagoras and Euclid which are derived from isosceles triangles (see Fig. 2) with two base internal angles of 72⁰ and a third internal angle of 36⁰, adding together to 180⁰, is well established in art from ancient Greek to modern times. Theodore Andrea Cook in his book The Curves of Life¹⁰ and D'Arcy Thompson in his book On Growth and Form¹¹ showed that the golden section is important, for example, in the understanding of the beautiful spiral shapes of various sea shells since it gives rise to an equiangular or logarithmic spiral (see Appendices A and B). We shall see also that the nonperiodic patterns produced by Roger Penrose^26,27 using just two tiles are based on the golden section.

 

Let us reflect on the fact that nowadays biologists believe that the beautiful and interesting structures of living creatures and plants arose from the process of Darwinian evolution produced by their very successful adaptation to the environment in which they lived. It is easy to understand, for example, that birds require a pair of right and left symmetrically shaped wings which are mirror images of each other, together with a symmetrically shaped lightweight body, to be able to fly through the air, and that land creatures require two pairs of right and left symmetrically shaped legs to walk on the ground under gravity, although one pair of symmetrically shaped legs suffices for human beings to walk upright. Furthermore, two symmetrically structured eyes are needed for stereoscopic vision and two symmetrically formed ears are needed for stereophonic hearing. Requirements such as these have led to the lovely symmetry of the living creatures of our world and so to their use as models for the artwork of humankind.

 

Spirals occur in many different contexts, both in nature and in art. The convolvulus plant climbs upwards in the form of a right-handed helix while the hop climbs in the shape of a left-handed helix. A fine example taken from architecture, cited by T. A. Cook, is the Palazzo Contarini del Bovolo in Venice with its delightful right-handed spiral staircase Scala del Bovolo. It is intriguing to discover that a feature of the Turbine Hall in the new millennium Tate Modern art gallery in London is the three very high towers with spiral staircases created by Louise Bourgeois.

 

Euclidean geometry is fundamental to the art of Islam. Islamic art is strongly based on various geometrical figures such as equilateral triangles, squares and many different regular polygons with sides ranging in number from 5 to 24, as has been beautifully illustrated in Keith Chritchlow's book on Islamic Patterns¹². Splendid examples of Islamic tessellations are to be found in Spain, for example in the Alhambra in Granada, and elsewhere in the Muslim world¹⁹.

 

Much of the pictorial art of Western Europe during the 12th to the 14th centuries presents a somewhat naive, rather unnatural and doll-like appearance. It possesses an almost symbolic form lacking in solid dimensionality that contrasts strongly with the art of the Greeks and Romans who portrayed people very realistically centuries before the birth of Christ. An exception to this was the marvellous early 14th century Italian painter Giotto di Bondone (1267?-1337) who painted people accurately and possessed a fine intuitive feeling for spatial relationships. But, in general, this unnatural character remained until the art of the Renaissance introduced some more reality into pictures in the late 15th century onwards^1,13 using the mathematics of perspective originated by the sculptor and architect Filippo Brunelleschi (1379-1446) and also the architect Battista Alberti (1404-72). Perspective was fully introduced into painting by, for example, the Italian artists Paolo Uccello (1397-1475), Piero della Francesca (1420-1492), Leonardo da Vinci (1452-1519) and Raphael (1483-1520), as well as the German artist and engraver Albrecht Dürer (1471-1528). It is worth emphasizing that Piero della Francesca was well known in his lifetime as a mathematician in addition to his fame as an artist, and that Leonardo da Vinci was greatly interested in mathematics as indeed was Dürer. They regarded a thorough knowledge of mathematics as essential for an artist and indeed wrote books on mathematical subjects such as plane and solid geometry.

 

Objective art and the use of perspective then flourished in the painting of buildings and landscapes until recent times. However a revolution occurred towards the end of the 19th century and the beginning of the 20th century that resulted in a great deal of modern art being rather abstract, mystical and non-objective. Although this art certainly possesses structure and pattern, it employs a lot of symbolism and does not show much direct connection with mathematics and moreover departs from the use of the recognized rules of perspective. Indeed some modern art often seems to deliberately avoid depicting the symmetry of nature and takes delight in the distortion and metamorphosis of the appearance of people and objects as was often done by Picasso and his contemporaries, albeit in an interesting, colourful, very beautiful and imaginative way²⁹.

 

However there are some notable exceptions to the metaphysical, surrealist and non-objective art of recent times, a particularly interesting example being the graphic work of the Dutch artist Maurits Escher (1898-1972)^2,14,25 much of which has a strong relationship to Islamic art. In fact Escher developed some of his ideas for his graphic art from his visits to the Alhambra in Granada, Spain where he drew pictures of the remarkable tiles that decorate the walls in beautiful periodic patterns. Escher was strongly influenced by mathematical ideas and produced, for example, interesting woodcuts illustrating non-Euclidean geometry.

 

Periodic patterns have also been used with great effect to produce beautiful textiles in many parts of the world such as India, Pakistan, and Persia. An example from the Victoria and Albert (V & A) Museum in London is a mid-17th century carpet decorated with a design based on pots and flowers possessing horizontal and vertical translation symmetries and vertical reflection symmetries. It is made from wool pile with cotton warps and silk wefts, and probably comes from Lahore.

 

In England the textiles, tessellations and wallpapers designed by William Morris (1834-96) illustrate various simple mathematical symmetries. An example, chosen from the V & A, of his ornate tiling, depicts a complex collection of flowers, stalks and leaves with a reflection symmetry. It was made in the factory of William De Morgan in 1876-7 for the bathroom in Membland Hall in Devon. Another example of the work of William Morris in the V & A is the furnishing textile Tulip and Willow made of block printed and indigo-discharged cotton. It possesses translation symmetries in both the vertical and horizontal directions. Other beautiful examples of the work of William Morris to be found in the Picture Library at the V & A that exhibit translation and reflection symmetries are his Pimpernel Wallpaper (1876) showing very large flower heads, which he hung in his dining room at Kelmscott House, his Bird Curtains (1877-8) which he used in the drawing room of Kelmscott House, and his Strawberry Thief pattern (1883) showing thrushes about to eat strawberries.

 

We have already noted that some modern art conspicuously possesses a non-objective, spontaneous and rather discordant dynamic character, freed from motif, which emanates largely from the unconscious mind and the emotional state of the artist. Yet, in contrast, much primitive artwork is objective and exhibits a surprisingly intimate connection with sophisticated geometrical symmetries and thus with mathematics, although with a truly imaginative and creative flair, and because of this it is to Primitive Art that we shall devote the first section of this article.

 

 

1. PRIMITIVE ART

 

 

The title of this section, Primitive Art, is the same as that used by previous authors^4,15 who were concerned with the art of the native peoples of Africa, Australia and New Zealand, Asia, North and South America, and elsewhere in the world. This art is often firmly and skillfully based on various patterns derived from the fundamental one-dimensional and two-dimensional symmetries of geometry. In no way does the use of the word 'primitive' imply a crude art form: indeed even the earliest artwork of mankind usually has some mathematical significance.

 

As long ago as the fifteenth century B.C., Mycenaean pottery jars were decorated with simple geometrical patterns such as the spirals on the jar found in a tomb in Ialysos on the Island of Rhodes dating from 1450-1400 B.C. on display in the British Museum. Somewhat later on in the tenth century B.C., known as the Protogeometric period (1050-900 B.C.), the Greeks used various geometrical patterns such as arcs and circles employing compasses and comb-like brushes to decorate their vases or jars, sometimes placed over graves, called amphora. Other simple geometrical patterns were also used, an example from Athens (950-900 B.C.) displayed in the British Museum, has a chequer-board design on the shoulder and three parallel wavy lines. In the full Geometric period, occupying the ninth and eighth centuries B.C., more elaborate designs such as continuous bands of meanders of various shapes sometimes with straight edges, zigzags, triangles, and less often with circles and semi-circles, were used to decorate two-handled vases and bowls or jars for mixing wine with water known as kraters. In the early eighth century animals such as horses, deer, goats and fowl were introduced into the decoration, and then in the latter part of the eighth century human figures, chariots and warriors were used. Examples are a krater from Athens c. 750 B.C., a late eighth century Athenian amphora with deer, goats and geese, and a late eighth century vase decorated with various geometrical designs, including a central flower-like symmetrical pattern with eight petals, from the island of Thera. These are discussed in rather more detail in the book on Greek Art written by John Boardman⁶.

 

Spirals have been found in many kinds of primitive art. In particular they have been found carved on massive stones in the Newgrange tumulus in Co. Meath, Ireland dating from about 5200 years ago in the Neolithic age.

 

Of the two spirals found connected together on the entrance stone of Newgrange tumulus, one has a right-handed sense of rotation and the other has a left-handed sense of rotation. A triple spiral is carved on one of the stones of the central chamber of the Newgrange tumulus. These double spiral shapes and triple spiral shapes are also found on Greek jars, an example being the black–figured amphora depicting Achilles and Penthesileia painted by Exekias and signed by him as potter (Athens 540-530 B.C.) which is on display in the British Museum. It is interesting to note also that M. C. Escher used a dual double spiral in a woodcut using three colours, namely Whirlpools, in which infinite lines of fish proceed from one limiting point to the other limiting point in both directions. This design has similarities to the Cornu double spiral discussed in Appendix B.  Another modern intriguing double spiral composed of nine-sided polygons has been constructed by Heinz Voderberg.

 

A splendid example of African primitive art is a beaded mask from the Cameroons, which is symmetrical about the vertical central axis and whose large circular ears possess an inner sixfold symmetry and an outer 24-fold symmetry, shown in the book on Primitive Art by Fraser¹⁵. We see that this primitive art is very beautiful and has great merit.

 

Another interesting and beautiful example of African primitive art given by Fraser¹⁵ is an ancestor screen from Ijaw, Nigeria having symmetry about a vertical central axis.

 

A further example this time from New Britain, is a warrior's shield, made of wood and dyed cane, which is symmetrical with respect to reflections in two perpendicular lines, apart from the small decorations at the top and bottom of the shield¹⁵. Each reflection produces a colour reversal.

 

Fundamental Geometrical Symmetries of Primitive Art

 

Much of the beauty of primitive art arises from its expression of the various types of the available geometrical symmetries. There are seven possible one-colour one-dimensional patterns similar to friezes or bands, there are seventeen possible two-colour one-dimensional patterns, seventeen possible one-colour two-dimensional patterns similar to wallpaper patterns, and there are forty-six possible two-colour two-dimensional patterns, many of which have been used by artists in various primitive societies and have been beautifully put together by Washburn and Crowe in their book Symmetries of Culture⁵.

 

The seven one-colour one-dimensional patterns are based on symmetries that involve translations, reflections, rotations, and glide-reflections, a glide-reflection being a translation in a given direction followed by a reflection in a mirror line parallel to the direction of the translation.

 

We denote them by the two-symbol notation xy where, if there is a vertical reflection x is m for mirror but otherwise 1; if there is a horizontal reflection y is m, if there is a glide-reflection but not a horizontal reflection y is g, if there is a half-turn but not a reflection or glide-reflection y is 2, but otherwise y is 1. These give rise to the seven cases 11, 1m, m1, 12, mm, mg, 1g. They are all repetitive patterns and so they are invariant under a translation in the horizontal direction. Ignoring their translational invariance, they possess the invariance properties that are characterized by the symmetries that are generated as shown in Table 1.

 

Table 1. The seven one-colour one-dimensional patterns.

 

11: No transformation other than a horizontal translation.

 

1m: Reflection in the horizontal line.

 

m1: Reflection in the vertical line.

 

12: Half-turn or twofold rotation.

 

mm: Reflection in the vertical line and reflection in the horizontal line.

 

mg: Reflection in the vertical line and a glide reflection in the horizontal line.

 

1g: Glide reflection in the horizontal line.

 

 

We have referred to the two perpendicular directions as vertical and horizontal but this designation is often just notional and is used here merely for convenience.

 

The seventeen two-colour one-dimensional patterns have been illustrated by Woods (1935)¹⁶ and are also displayed in the book Symmetries of Culture by Dorothy K. Washburn and Donald W. Crowe⁵. They can be represented symbolically using the form G/G¹ where difference of colour is disregarded in G and colour is preserved in G¹. This gives rise to a four-symbol notation as follows:  11/11, 12/11, 12/12, 1m/11, 1m/1m, 1m/1g, 1g/11, m1/11, m1/m1, mm/12, mm/1m, mm/m1, mm/mm, mm/mg, mg/1g, mg/m1, mg/12. They are generated as given in Table 2.

 

 

Table 2. The seventeen two-colour one-dimensional patterns.

 

11/11: Horizontal translation through one step transforms one colour into the other colour producing colour reversal.

 

12/11: Twofold rotation transforms one colour into the other colour producing colour reversal.

 

12/12: Alternate twofold centres where a twofold rotation produces colour reversal.

 

1m/11: Reflection in the horizontal mirror axis produces colour reversal.

 

1m/1m: Reflection in the horizontal mirror axis leaves colours unchanged but a one-step horizontal translation produces colour reversal.

 

1m/1g: Reflection in the horizontal mirror axis and a one step horizontal translation both produce colour reversal.

 

1g/11: Glide reflection along the horizontal mirror axis through one step produces colour reversal.

 

m1/11: Reflection in vertical mirror lines produce colour reversal.

 

m1/m1: Reflection in alternate vertical mirror lines produce colour reversal.

 

mm/12: Reflection in horizontal and vertical mirror lines produce colour reversal.

 

mm/1m: Reflection in the horizontal mirror axis preserves colours but reflection in all the vertical mirror lines produces colour reversal.

 

mm/m1: Reflection in the horizontal mirror axis produces colour reversal but horizontal translation leaves colours unchanged.

 

mm/mm: Reflection in the horizontal mirror axis leaves colours unchanged but reflection in alternate vertical mirror lines produces colour reversal.

 

mm/mg: Reflection in the horizontal mirror axis and reflection in alternate vertical mirror lines all produce colour reversal. Also a glide reflection along the horizontal mirror axis through one step preserves colours.

 

mg/1g: Reflection in vertical mirror lines produce colour reversal but a glide reflection along the horizontal mirror axis through one step preserves colours.

 

mg/m1: Reflection in vertical mirror lines preserve colours but a glide reflection along the horizontal mirror axis through one step interchanges colours.

 

mg/12: Reflection in vertical mirror lines and a glide reflection along the horizontal mirror axis through one step interchange colours.

 

 

The seventeen one-colour two-dimensional patterns were first listed by the Russian crystallographer Fedorov in 1891.

 

There are five primitive cells for these two-dimensional patterns. They are:

 

A: parallelogram.

B: rectangle.

C: rhombus.

D: square.

E: hexagon.

 

These cells produce a lattice by means of translations.

 

Together with their crystallographic symbols the patterns are generated as indicated in Table 3 derived from those given by the geometer H. S. M. Coxeter in his article on Coloured Symmetry in M. C. Escher: Art and Science² and in his book Introduction to Geometry¹⁷.

 

Table 3. The seventeen one-colour two-dimensional patterns.

 

p1: Two independent translations.

Parallelogram lattice.

 

p2: Half-turns about three centres which are not all in a straight line.

Parallelogram lattice.

 

pg: Two parallel glide reflections.

Rectangular lattice.

 

pm: Two parallel reflections and a translation along the direction of the reflection lines.

Rectangular lattice.

 

cm: A reflection and a parallel glide reflection.

Rhombic lattice.

 

pgg: Two perpendicular glide reflections.

Rectangular lattice.

 

pmg: A reflection and half-turns about two points equidistant from the reflection axis or mirror line.

Rectangular lattice.

 

pmm: Reflections in the four sides of a rectangle.

Rectangular lattice.

 

cmm: Two perpendicular reflections and a half-turn about a centre that is not on either of the mirror lines.

Rhombic lattice.

 

p4g: A reflection and a quarter-turn.

Square lattice.

 

p4: Two quarter-turns.

Square lattice.

 

p4m: Reflections in the three sides of a right-angled isosceles triangle with two 45⁰ angles.

Square lattice.

 

p3m1: Reflections in the three sides of an equilateral triangle.

Hexagonal lattice.

 

p31m: A reflection and a threefold rotation.

Hexagonal lattice.

 

p3: Two rotations through 120⁰.

Hexagonal lattice.

 

p6: One threefold and one sixfold rotation.

Hexagonal lattice.

 

p6m: Reflections in the three sides of a bisected equilateral triangle with angles of 30⁰, 60⁰, 90⁰.

Hexagonal lattice.

 

In this table the letter p denotes a primitive cell, the letter c denotes a centred cell, the letter m denotes a reflection axis or mirror line, and the letter g denotes a glide reflection.

 

The centred cell only occurs in a rhombic lattice of points. It is a rectangle with the mid-points of its sides at the vertices of the rhombus and has twice the area of the rhombus.

 

The forty-six two-colour two-dimensional patterns have been illustrated by Woods (1936)¹⁶ and are also displayed in the book Symmetries of Culture by Dorothy K. Washburn and Donald W. Crowe⁵. They may be represented by the notation G/G¹, where the difference between the two colours is disregarded in G but retained in G¹.

 

A simple example of a two-colour two-dimensional pattern is a chess-board whose chequer-board design occurs commonly in primitive art such as on the amphora from Athens mentioned previously and on display in the British Museum. The chess-board has the crystallographic pattern classification p4m/p4m. In this pattern the mirror lines that pass along the two perpendicular sides of the squares interchange the two colours. However the four mirror lines that pass through the centre of a square in the two directions parallel to the sides and along the two diagonals of the square leave the two colours invariant. A rotation through 90⁰ about a twofold center, where four squares meet, interchanges the two colours.

 

We will not classify the generators for the two-colour two-dimensional patterns in a table although we shall introduce some examples of art works that exemplify their symmetry characteristics both here and when we discuss the graphic work of Escher in section 5 on modern art.

 

Primitive art from the different cultures throughout the world, not necessarily from long ago, such as are found in South America, North America and Africa take the form of beautiful ceramics, bowls and jars, baskets, wooden vessels, mats, textiles of various kinds such as clothes and blankets, shields, masks and mosaics. They are usually of a practical nature although they are often used mainly for decorative purposes.

 

In the following we will give a few examples of primitive art works that exhibit some of the various symmetry classes. They show that the artists who created them had an excellent, if only intuitive, understanding of geometry.

 

Different cultural groups favour different symmetries for their designs. The simplest symmetry patterns tend to predominate. For example in the one-colour one-dimensional, or band, designs of Inca pottery, Aschers (1981)⁵ found that 40 per cent were of the horizontal and vertical reflection symmetry class mm, 20 per cent were of reflection symmetry class m1 while 11 per cent were of reflection and glide reflection symmetry class mg and these preferences express their cultural identification.

 

With the progression of time the symmetries used by a given cultural group may change. Thus Zaslow and Dittert (1977)⁵ have found that the red-on-buff band designs in the interior of the Hohokam ceramic bowls changed from the one-colour one-dimensional translation symmetry class 11 to the rotational symmetry class 12. In a later phase the designs changed to include the one-colour two- dimensional glide reflection symmetry class pgg although the rotational symmetry pattern was predominant to begin with.

 

An example of a one-dimensional one-colour pattern is a twined basket from the north west coast of California exhibiting an mm symmetry that belongs to the collection of the California Academy of Sciences in Golden Gate Park in San Francisco. It has been photographed by Christopher Thomas and is given in the book by Washburn and Crowe⁵.

 

Examples of one-dimensional two-colour patterns are a Cheyenne beaded pouch with a mm/mm symmetry pattern, and a Germantown Navajo rug with a mm/mg symmetry pattern in the central band, which however is not completely accurate. They are to be found in the California Academy of Sciences in San Francisco, and have again been photographed by Christopher Thomas⁵.

 

Next we give some examples of two-dimensional patterns.

 

First we consider some one-colour patterns:

 

A Mohave ceramic scoop has the pmg symmetry pattern in which a reflection in a mirror axis through the middle of any black triangle leaves the colours invariant. There is a glide reflection in the perpendicular direction.

 

A Huichol indian shoulder bag from the western Sierra Madre in Mexico possesses a p4m symmetry pattern which is invariant with respect to rotations through 90⁰ and mirror reflections in perpendicular axes as well as in axes along the diagonals.

 

An Acoma Pueblo ceramic jar from New Mexico has a beautiful p2 symmetry pattern that is invariant under twofold rotations through 180⁰.

 

A Navajo indian woolen rug made about 1940 has a pgg symmetry pattern with glide axes in two perpendicular directions. This is a one-colour pattern since the white hooks can be superimposed on the white hooks and likewise the black hooks can be superimposed on the black hooks but the white and the black hooks cannot be superimposed upon each other.

 

Another Navajo indian woolen rug made about 1930 has a pmm symmetry pattern which is invariant under reflections in two perpendicular directions. This is also a one-colour pattern since the designs in the white and dark diamond areas are slightly different and cannot be superimposed on each other.

 

Next we consider some examples of two-colour patterns.

 

A pre-Columbian Peru bag from Nazca has a p2/p1 symmetry pattern composed of black hooks and white hooks. There are rotation centres between the black and white hooks that interchange colours but there are no rotations which keep the two colours unaltered.

 

A Woodlands indian, Great Lakes ribbon blanket has a pmm/pm symmetry pattern with reflection axes in the vertical direction which keep the colours unaltered but reflection axes in the horizontal direction which interchange colours. All of the rotation centers lie on the reflection axes and they all interchange colours.

 

A basket from central Africa has a cmm/cm symmetry pattern in which reflections in the axes that bisect the isosceles triangles do not change colours but reflections in the perpendicular axes along the bases of the triangles interchange the two colours. Also twofold rotations through 180⁰ interchange colours.

 

A Middle Horizon, South Coast, Peru textile used as a burial wrapping has a pg/p1 symmetry pattern in which there are glide axes going between the diamonds containing the small birds that face in opposite directions. The colours of the diamonds are interchanged on performing reflections in the axes through the centres of the diamonds parallel to the translation axes.

 

An Achomawi twined basket hat from California has a p2/p2 symmetry pattern in which the colours are interchanged when a translation is performed in the horizontal direction but unchanged when translated in the perpendicular direction.

 

A Navajo indian blanket or rug with a cmm/pmm symmetry two-colour pattern has a design in which black and white colours are interchanged along the diagonal glide lines but no colour interchanges occur about the reflection lines.

 

Finally we mention a plaited basket from Samoa with a cmm/pgg symmetry pattern in which each rectangle contains four horizontal strips and five vertical strips and so only a 180⁰ rotation can produce invariance. A rotation through 180⁰ about the centres between the different coloured steps of each cell interchanges the two colours. Further a reflection in a horizontal or vertical mirror line interchanges colours also.

 

These examples of works of art created by peoples belonging to the so-called primitive cultures are evidently firmly based on a sophisticated understanding of the complex symmetries of plane geometry.

 

They are discussed fully in the book Symmetries of Culture by Washburn and Crowe⁵ where many more cases of great interest are given.

 

 

 

2. MUSIC

 

 

It is well understood that there is a strong connection between music and mathematics. Indeed, as we shall see, both Johann Sebastian Bach and, perhaps surprisingly, Chopin would surely have recognized such a relationship.

 

Pythagorean Scale and the Comma of Pythagoras

 

The first musical scale of 5 tones and 2 hemitones is often associated with the ancient Greek mathematician Pythagoras. However the Pythagorean scale, that we shall denote by the usual letters C, D, E, F, G, A, B, C forming an octave, contains a difficulty known as the comma of Pythagoras. To demonstrate this, consider the notes of an octave. According to the Pythagorean scale, the ratios of the frequencies of the notes are given by the fractions listed in Table 4.

 

 

Table 4. The Pythagorean musical scale and the equal-temperament scale.

 

 

	Pythagorean scale		Equal-temperament scale
C	1		1
		tone		tone
D	9/8=1.125		(12Ö2)2 =1.1224…
		tone		tone
E	81/64=1.2656…		(12Ö2)4 =1.2599…
		hemitone		semitone
F	4/3=1.3333		(12Ö2)5 =1.3348…
		tone		tone
G	3/2=1.5		(12Ö2)7 =1.4983…
		tone		tone
A	27/16=1.6875		(12Ö2)9 =1.6817
		tone		Tone
B	243/128=1.8984…		(12Ö2)11 =1.8877…
		hemitone		semitone
C	2		2

 

 

The upper C of the octave has twice the frequency of the lower C. Now there are seven octaves from the lowest C to the highest C of a piano keyboard and so the ratio of the frequency of the highest C to the lowest C is 2⁷ = 128. But if we go up the notes of a musical instrument tuned according to the Pythagorean system rising by 12 intervals of a fifth or five notes of the scale, each having a frequency ratio of 3/2 and corresponding to 3 tones and a hemitone, as follows:

 

C ® G ® D ® A ® E ® B ®

G flat ® D flat ® A flat ®E flat ® B flat ® F ® C

 

the frequency ratio of the highest C to the lowest C becomes (3/2)¹²=129.746... producing a discrepancy amounting to the factor of 1.0136... which is the comma of Pythagoras.

 

Equal-temperament Scale and Key Signatures

 

To overcome this problem the mathematician and musician Mersenne⁹, noted in particular for his discussion of those prime numbers which have the form   2ⁿ - 1 where n is also a prime number, introduced the equal-temperament scale described in his Harmonie Universelle (1636-37) which makes each of the 12 semitones of every octave of a piano keyboard have the same frequency ratio ¹²Ö2=1.05946... . This means that the 12 major scales, starting at the keys C, D flat, D, E flat, E, F, G flat, G, A flat, A, B flat, B, will only differ in pitch so that if an old-fashioned gramophone record of the note C, which is normally standardized to a frequency of 262 vibrations per second, is played at an appropriate higher speed of rotation the sound will be precisely the same as the corresponding higher key. This observation similarly applies to the 12 minor keys.

 

Using the equal-temperament scale composers were now able to write music for the remote keys. This was not possible with the Pythagorean scale, or some of its earlier modifications, which confined musicians to keys not far away from the key of C major. However this meant that the notes of the equal-temperament scale were never in precise harmony, for example in the scale of C major the note G should have the frequency ratio of 3/2 = 1.5 referred to the note C for exact harmony whereas in the equal-temperament scale it is (¹²Ö2)⁷ = 1.4983... , and the note A should have the frequency ratio 27/16 = 1.6875 for exact harmony whereas it is (¹²Ö2)⁹ = 1.68179... in the equal-temperament scale, as can be seen from Table 4.

 

Johann Sebastian Bach wrote his two sets, Book I and Book II, of Preludes and Fugues using the 24 keys of the equal-temperament scale in the straight-forward order C major, C minor, D flat major, D flat minor, D major, D minor, E flat major, E flat minor, E major, E minor, F major, F minor, G flat major, G flat minor, G major, G minor, A flat major, A flat minor, A major, A minor, B flat major, B flat minor, B major, B minor. Thus the two books have a total of 48 preludes and fugues.

 

Chopin also wrote a set of 24 preludes (but no fugues) in his Opus 28 although in the order major to minor and of increasing fifths. Thus he chose the order C major, A minor, G major, E minor, D major, B minor, A major, F sharp minor, E major, C sharp minor, B major, G sharp minor, G flat major, E flat minor, D flat major, B flat minor, A flat major, F minor, E flat major, C minor, B flat major, G minor, F major, D minor, as displayed in the regular dodecagon or twelve-sided polygon given in Fig. 1.

Fig. 1

 

 

In this diagram the 12 major key notes C to F are given in clockwise order round the outer rim of the dodecagon with the key of C major at the top. Within the dodecagon the 12 minor key notes A to D are again given in clockwise order round the polygon with the key of A minor at the top. Thus, bearing in mind that C sharp is the same as D flat and G sharp is the same as A flat we see that the minor key notes are displaced anticlockwise around the dodecagon by a quarter-turn relative to the major key notes.

 

We notice that the order in which the keys were used by Chopin in his 24 preludes begins at the C major key at the top of the polygon, then goes to the corresponding A minor key immediately within the polygon, then to the G major key next clockwise along the outer rim of the polygon, then goes to the corresponding E minor key within the polygon, and so on right round the polygon to the keys of F major and D minor. There is a clear mathematical pattern to this order of keys. As we go round the polygon in the clockwise sense both the major and minor keys increase by fifths with the minor keys being thirds, equivalent to a tone plus a semitone, below the major keys. The same order of the keys was also used later on by the Russian composers Scriabin in his 24 Preludes Opus 11 and Shostakovich in his 24 Preludes Opus 34, but not by the French composer Debussy in his Preludes.

 

The numbers of sharps # or flats b in the respective key signatures are as listed in Table 5. Note that F sharp major is the same as G flat major and D sharp minor is the same as E flat minor.

Table 5. The numbers of sharps and flats in the key signatures of the 12 major and 12 minor scales.

 

 

			sharps #
C major	A minor	0
G major	E minor	1	F
D major	B minor	2	FC
A major	F sharp minor	3	FCG
E major	C sharp minor	4	FCGD
B major	G sharp minor	5	FCGDA
F sharp major	D sharp minor	6	FCGDAE

 

 

			flats b
G flat major	E flat minor	6	BEADGC
D flat major	B flat minor	5	BEADG
A flat major	F minor	4	BEAD
E flat major	C minor	3	BEA
B flat major	G minor	2	BE
F major	D minor	1	B

 

 

It is worth remarking here that if the scale of Pythagoras is set out on a diagram such as Fig. 1, it is endless since the note B sharp which we arrive at after going round the figure once is no longer in the same position as the note C (to which it is identical on the piano keyboard) due to the comma of Pythagoras. The note G in the equal-temperament scale has the frequency ratio (¹²Ö2)⁷=1.4983... relative to the note C whereas in the Pythagorean scale the note G has the frequency ratio 1.5. Thus a diagram based on the dodecagon is not appropriate for the Pythagorean scale and it is necessary to use a circular spiral figure that is not closed.

 

At the Edinburgh Festival in 1997 the excellent pianist Andras Schiff gave a recital of Book I of the Preludes and Fugues by Johann Sebastian Bach, in the 24 keys of the equal-temperament scale. Each of the Bach 24 pieces of music has a tuneful preliminary part called a prelude followed by a complex contrapuntal part known as a fugue. They involve complicated counterpoint based on the rules of harmony and require great dexterity to play on the part of the performing artist. In an interview on the wireless prior to the recital he said that he thought of the keys as ranging over a spectrum of colours from the “white key” of C major to the “black key” of B minor. Indeed it was Beethoven who first referred to the key of B minor as a “schwarze tonart”. Both Bach and Chopin wrote particularly soulful music in the key of B minor. Thus the Bach Prelude No. 24 in B minor as well as his Mass in B minor, and the Chopin Prelude No. 6 in B minor, are characteristically rather dark pieces of music. Frederick Niecks, in his Life of Chopin, quotes George Sand as saying that the Chopin Prelude No. 6 was composed one evening when the rain was falling, and that it “precipitates the soul into a frightful depression”. However it may be that this composition was actually the so-called raindrop Prelude No. 15 in D flat major which demonstrates the difficulty in ascribing a particular kind of emotion to a piece of music.

 

It is also interesting to note that the pianist Andras Schiff said that he regards Bach as a sculptor and sculpture is just how Bertrand Russell described the beauty of mathematics in the essay on The Study of Mathematics in his collection entitled Mysticism and Logic¹⁸.

 

Time-signatures

 

Music also has an important dependence on time that is another obvious connection with mathematics. Each note has a given time duration denoted by, for example a semibreve or whole-note, a minim or half-note, a crotchet or quarter-note and a quaver or eighth-note. Each bar of music has a time-signature composed of two numbers  which expresses the way in which the notes are played as time progresses forward. Here m denotes the number of beats in a bar and n denotes the time duration of the beat, for example   denotes four crotchet beats in a bar known as common time often indicated by C,   denotes three crotchet beats in a bar,  denotes three minim beats in a bar and  denotes two quaver beats in a bar. The rhythm of music is a clear indication of the mathematical connection of music with time that is evident to the ear.

 

That music is an art form that depends essentially on the forward progression of time differentiates it from the static art forms of painting, drawing, sculpture and architecture. It provides music with the ability to produce a highly intense emotional experience that is rarely given by the static art forms.

 

Characteristics of Scales

 

As we have already pointed out, in a piano accurately tuned to the equal-temperament scale, every semi-tone is equal so that the 12 major scales and the 12 minor scales separately only differ in pitch. Thus the feeling that the different scales possess contrasting characteristics should be rather subjective although nevertheless believed by some eminent people including the mathematician and physicist Helmholtz (1821-1894)⁹. That the 24 scales are felt to sound different to the ear may be due just to the fact that each scale begins at a different key of the 12 keys comprising an octave and each scale has a major form and a minor form in which the third note is a semitone lower than in the major scale giving it a characteristic melancholic sound. Of course for a pianist each scale has a different arrangement of white and black piano keys so that each scale feels different to the touch of the fingers when played. For example, the keys of B major and D flat major have all five black notes whereas the key of C major has no black notes. Although the B major scale has five black notes it is worth appreciating that Chopin recommended this scale for beginners since the fingers of a hand fit naturally onto the keys of a piano in this case.

 

However it may be that musicians who can associate different colours with different keys have a sense of absolute pitch which is relatively uncommon although we know that Mozart had this sense of absolute pitch to an extraordinary high degree even as a very young child.

 

It must also be remembered that when any note is played on a piano or other musical instrument it is accompanied by overtones or natural harmonics, that is by tones which have frequencies which are pure multiples of the fundamental note, and the combination of the fundamental note and its overtones produces a rich musical sound.

 

Other composers, as well as Beethoven, have also thought of music as being associated with colours. For example the British composer Arthur Bliss wrote a Colour Symphony. The first movement of this symphony is named Purple and was associated by Arthur Bliss with the semi-precious stone amethyst and with pageantry, royalty and death. The second movement is called Red and was associated by the composer with the precious stone ruby and with wind, revelry, courage and magic. The third movement is named Blue and was related to sapphire, deep water, skies, loyalty and melancholy. The final movement is named Green and was associated with the precious stone emerald and also with hope, joy, youth, spring and victory. Bliss said that colour was very much in his mind when he wrote this symphony prior to the time of its first performance in 1922.

 

Mathematical Nature of Bach's Music

 

It is evident that the various associations with each colour in Bliss's symphony have a lot to do with emotions and feelings although absolutely nothing to do with mathematics. But music has structure and indeed possesses an abstract and characteristically mathematical nature in the case of the Preludes and Fugues by Bach.

 

Much of Bach's music, because of its strict observance of the rules of harmony and the precision of its rhythms and phrasing, gives the listener the impression of being characterized by a mathematical discipline although with a great emotional intensity. Again the pianist Andras Schiff, in a BBC television broadcast on Bach, said that he found that playing Bach's Preludes and Fugues had a cleansing effect on him and was pure to the spirit and the soul. This suggests a purity that has been often associated with mathematics. Indeed the subject is often called pure mathematics when applications are not involved.

 

A further example that can be provided in favour of the mathematical nature of Bach's music is the series of complex pieces called the Musical Offering that he composed in Leipzig in 1747 and were based upon a theme given by Frederick the Great, the King of Prussia, to Bach on a visit he made to Potsdam. The title-page contains the inscription Regis Iussu Cantio Et Reliqua Canonica Arte Resoluta which roughly translated means “by the King's Command the Theme and the Remainder Resolved by the Art of the Canon”. The first letters of this inscription in Latin are RICERCAR which taken from the Italian word ricercare implies a piece of research and is also equivalent to the French word recherche. One of these pieces of music is a canon in the key of C minor with a remarkable symmetry: it has two themes performed together, the second of which is the original theme played backwards in time. It is called a Canon Recte et Retro or sometimes a Crab-Canon.

 

Not only does music have form and structure but so does painting, and art generally, possess considerable structure or pattern. Without structure, music would just be a discordant combination of sounds, and without pattern paintings would just be composed of chaotic patches of colour, rather like one might suppose a new-born child sees the world for the first time.

 

 

It is well understood that it is pattern which is the essence of geometry and indeed, in many respects, mathematics generally. Without pattern we have just sensations and feelings, corresponding to the eye that peers inward. But the eye also looks outwards and perceives structure in the universe and this is what mathematics subjects to detailed analysis strictly based on logic. The search for structure, for example in the motion of the sun, the moon, the planets and the fixed stars in the sky, has been associated with religion because religion presupposes the existence of a creator who made all things and imposed harmony on the cosmos. And geometrical patterns are the basis of Islamic art that I shall be discussing in the next section.

 

 

3. ISLAMIC ART

 

 

In the art of Islam, in its purest form, only patterns and colour are permitted, with the purpose of revealing and mirroring the underlying harmonic structure of the universe as well as producing visual delight. No human figure or the shape of any living creature may be present in the decoration of mosques or religious buildings of any sort.

 

Arabic art is strongly based on various notions such as displacement, reflection, rotation, shape and symmetry that are all fundamental to the study of geometry, and is closely related to the periodic structure of crystals. We recall that the Russian crystallographer Fedorov first listed the seventeen one-colour two-dimensional patterns in 1891.

 

This means, of course, that Islamic art is concerned essentially with abstract geometrical forms and is consequently very limiting and produces a great challenge to the artist.

 

The Arabs were great mathematicians who filled the role vacated by the ancient Greek geometers until the Renaissance mathematicians of Western Europe began to appear on the scene in the late 15th century.

 

Wonderful examples of Islamic art can be found in Spain at the Alhambra in Granada and other places throughout the Moslem world such as mosques in Persia, Pakistan, India, Turkey and Egypt¹⁹.

 

Ceramic tiles and mosaics arranged in various kinds of geometrical designs were used to decorate the walls, ceilings and domes of mosques as well as all sorts of other buildings.

 

These Islamic designs have been classified and discussed in considerable detail by Keith Critchlow in his book on Islamic Patterns with the subsidiary title An analytical and Cosmological Approach¹². They include repeating patterns based on grids of regular polygons such as equilateral triangles, squares, regular pentagons, hexagons, heptagons, octagons, and regular polygons with 9, 10, 12, 14, 16 and 24 sides. Almost imperceptibly irregular pentagons, hexagons and heptagons were also used. These grids were employed by the Islamic mathematician-artists to construct beautiful and intricate patterns composed of, for example, polygons, stars, petals and arrowheads.

 

Basic Islamic Designs and Fundamental Regular Polygons

 

The complex structure of Islamic patterns has been discussed in considerable detail in the book by Keith Critchlow¹². Their composition can be best understood by examining an illustration from this book of the fundamental regular polygons having three to nine sides, namely the triangle, square, pentagon, hexagon, heptagon, octagon and nonagon, their vertices on circles, with some basic Islamic designs composed out of an interwoven tracery. There are seven patterns in this illustration:

 

Pattern A has a basic regular hexagon inside the equilateral triangular grid.

 

Pattern B has a flower, in the form of a cross, with four petals inside the square grid.

 

Pattern C has a flower with five petals composed of slightly irregular hexagons surrounding a pentagonal star within the regular pentagonal grid.

 

Pattern D has a flower with six petals composed of basic regular hexagons surrounding a hexagonal star within a regular hexagonal grid. It is interesting to see that a star of David, composed of two equilateral triangles, is produced by connecting the mid-point of the top side of the hexagon with the mid-points of its third and fifth sides and connecting the mid-point of the bottom or fourth side of the hexagon with the mid-points of its second and sixth sides.

 

Pattern E has a flower with seven petals composed of slightly irregular hexagons surrounding a seven-pointed star with seven arrowheads, all within a regular heptagonal grid.

 

Pattern F has a flower with eight petals composed of irregular hexagons surrounding a eight-pointed star made from two superimposed squares together with eight arrowheads.

 

Pattern G has a flower with nine petals composed of irregular elongated hexagons surrounding a nine-pointed star and nine arrowheads, all within a complicated grid derived from a nonagon (also known as an enneagon).

 

These patterns have been given a highly mystical and metaphysical interpretation within the Muslim religion that is described in some detail in Critchlow's book but which we will not discuss here.

 

Designs based on a 24-fold symmetry have been used not only in Islamic art but also elsewhere, for instance in the art of the Renaissance, an example being the 15-16th century paving within the 14th century Cathedral in Siena. In this paving there is a 24-spoked wheel composed of columns and possessing rotational symmetry inside a square pattern with an imperial eagle at its centre.

 

Finally let us recall that the graphic work of Maurits Escher in this century was strongly influenced by the remarkable Islamic tessellations he viewed in the Alhambra in Granada.

 

 

4. RENAISSANCE ART

 

 

We shall return to art based on repeating patterns later on in this article. But for now we shall turn our attention to the pictorial art of Western Europe, much of which, at its commencement, had a strong religious basis, as did the art of Islam, although of an entirely different nature. In fact the early Italian art of the 13th and 14th centuries was much devoted to a pictorial description of various biblical personages and events. In many respects this art was symbolic and no great attempt was made to produce pictures which gave a true description of reality with the exception of the first great artist of the Renaissance, the 14th century artist Giotto di Bondone (1267?-1337) who showed a fine intuitive feeling for spatial relationships as can be seen from his fresco Confirmation of the Rule of Saint Francis painted about 1325. In his Lives of the Artists the artist and biographer Vasari²⁰ writes that the use of foreshortening by Giotto was much praised and introduced a new approach to pictorial art.

 

Perspective

 

In the 15th century a number of artists began to introduce rather more reality into pictures by making use of the mathematics of perspective and in keeping with the new scientific model of the universe that was being developed at that time. These included the sculptor and architect Filippo Brunelleschi (1379-1446), often thought of as the originator of perspective about or perhaps before 1413, the architect and man of letters Leon Battista Alberti (1404-72) who wrote a short treatise on painting Della Pittura (1436) which contained a dedication to Brunelleschi in its preface and included the first published description of one-point perspective, the artist Paolo Uccello (1397-1475), and the universal artist, mathematician, scientist and engineer Leonardo da Vinci. In addition we have the mathematician and artist Piero della Francesca (c. 1415/20-92) who wrote a book on perspective De Prospectica pingendi (c. 1474) and a book Libbellus de quinque corporibus regularibus (c. 1480) on the five regular or Platonic solids: the tetrahedron with four congruent equilateral triangular faces, the cube with six congruent square faces, the octahedron with eight congruent equilateral triangular faces, the dodecahedron with twelve congruent regular pentagonal faces, and the icosahedron with twenty congruent equilateral triangular faces. In this book he also looks at five of the thirteen Archimedian solids, namely the five truncated regular solids that he is generally regarded as having rediscovered first. Piero also wrote a book called Trattato d'abaco on arithmetic, algebra and geometry including a discussion of two of the Archimedian solids, the truncated tetrahedron with four equilateral triangular faces and four regular hexagonal faces and the truncated cube with eight equilateral triangular faces and six regular octagonal faces.

 

It is interesting to note in this context that the discoverer of the three laws governing the motions of the planets, Johannes Kepler (1571-1630), wrote a treatise in 1619 entitled Harmonices mundi libri V or Five Books of the Harmony of the World in which there is a discussion of convex polyhedra including the thirteen Archimedean solids whose faces are not all identical.

 

Also, the remarkable German artist, metal and wood engraver Albrecht Dürer made a set of four woodcuts concerned with the use of perspective called the Designer Woodcuts. Dürer was very interested in mathematics, like the Italian artists before him, and wrote a book on geometry Underweysung der Messung (c. 1525) treating the subject of instruction on measurement with compass and ruler as well as other geometrical topics. It is in four parts: the first part is on plane curves such as conic sections and spirals; the second part is on regular polygons; the third part is on pyramids, cylinders and various instruments such as sundials; and the fourth part is on polyhedra and perspective. Dürer also wrote a book in four parts Vier Bucher von menschlicher proportion (1523) on human proportion from a truly geometrical although characteristically individualistic point of view. In addition he showed a considerable interest in the symmetry of other living creatures and, for example, painted watercolours of a young hare, the head of a roebuck, and a sea crab.

 

One of the first painters to use perspective was the Florentine Renaissance artist Paulo Uccello. An example of his work is The Profanation of the Host which was originally an altar-piece composed of a sequence of six episodes. The first two of these clearly illustrates his use of linear perspective in the directions of the black and white floor tiles, arranged in a chequer-board pattern, and the lines of the walls and ceiling. This set of pictures painted about 1466 is to be found in the Galleria Nazionalle della Marche at Urbino.

 

A beautiful illustration of the use of perspective can be found in the painting by Raphael of the Marriage of the Virgin or 'Sposalizio' showing a sixteen sided symmetrical building in which the vanishing point is clearly discernible^1,13. Another remarkable painting in which the vanishing point can be readily inferred is the Annunciation by the 15th century artist Carlo Crivelli (active 1457-d. 95) in the National Gallery in London, perfectly illustrating what has come to be known as 'laser beam theology': a pencil of rays of light descends from heaven, through a conveniently constructed hole in a wall, passing through a hovering dove representing the Holy Spirit and then onto the head of the Virgin Mary¹³.

 

As the art of the Renaissance developed, perspective was increasingly used in the composition of pictures, as can be well seen in the art of Dürer, for example his engraving of St. Jerome in His Study²¹, the art of Sandro Botticelli (1446-1510), Raphael, Leonardo da Vinci, and many others. Although Botticelli was not an important figure in the development of perspective he made use of the method in his art, for example in the Three Miracles of Saint Zenobius on display in the National Gallery of London and which he painted about 1500. Although the buildings in this picture are in perspective it depicts three events in the life of Saint Zenobius that remarkably took place at different times.

 

The vanishing point of linear perspective can be used to accentuate a particular aspect of a painting such as occurs in the Last Supper by Leonardo da Vinci where the vanishing point is at the head of Christ. Another beautiful example is the Circumcision by Signorelli (1450-1523) who was trained by Piero della Francesca and as a consequence became interested in geometry. In this painting from the National Gallery London, the lines marked out by the colourful paving stones point directly to the knife used by the mohel, that is the man who is about to carry out the religious circumcision operation on the baby Christ.

 

The 17th century Dutch painter Pieter de Hoogh (1629-84) was able to create a very realistic feeling of depth in his pictures as can be seen in the painting of an Interior with a Woman Drinking with Two Men and a Maidservant to be found in the National Gallery London¹³.

 

Also the Dutch artist Jan Vermeer (1632-75) painted many pictures that showed his good understanding of perspective as in The Music Lesson. Philip Steadman has constructed an interesting detailed model of the room and its contents that are depicted from various points of view in a number of Vermeer's paintings including The Music Lesson.

 

Symmetry is an important aspect of both art and mathematics. It can be perceived clearly in the art of Western Europe as well as in the art of Islam. But whereas symmetry is precisely defined in Islamic art, even when it depicts living creatures, such as in the 14th century Moorish silk textile in a Toulouse collection¹⁹ depicting colourful imaginary birds and their mirror images, the art of the Western Europe tends only to allude to symmetry as can be seen in the drawing of a pair of horses and riders by Leonardo in a study for the Adoration of the Kings (1481)²², and the painting of the Three Graces by Raphael which also illustrates the fascination of artists with the symmetrical beauty of the female human form. The Three Graces may have been based on a Hellenistic sculpture group of which a copy was found in Rome in the fifteenth century  (although it is now in Siena) and which also can be seen copied as a wall painting in Pompei.

 

The interest of the artist and mathematician Piero della Francesca in perspective and symmetry is well exemplified in his painting Ideal Town where the buildings with their arcades on either side of the square are very symmetrically situated relative to the central cylindrical building and the perspective is easily distinguished by the paving stones in the square. There is perhaps a certain resemblance to the piazza in front of the octangular Baptistry in Florence whose external walls were originally built of sandstone but were subsequently covered in white Carrara marble and Green marble from Prato.

 

The German artist Hans Holbein the Younger (1497/8-1543), who spent some time in England, exhibited the general interest in mathematics and astronomy, art and music by his magnificent double portrait The Ambassadors which shows not only the two diplomats Jean de Dinteville and Georges de Selve but also a variety of scientific objects such as globes and astronomical instruments as well as a six-stringed lute and a case of flutes. In this picture Holbein also painted a peculiar diagonally shaped object that can be seen to be a distorted skull, an indication of mortality, if viewed from an appropriate position on the far right-hand side. Among the objects displayed on the top of the high table is a celestial globe, a portable cylindrical sundial, a quadrant, and a six-faced polyhedral sundial made of ivory with a magnetic compass set into its upper face. Also there is a torquetum, together with its plumb-line, for determining the positions of stars and planets.

 

Geometry of Piero della Francesca

 

Next, I wish to draw your attention to a particularly remarkable painting also by Piero della Francesca called The Baptism of Christ which can be found in the National Gallery, London¹³. This picture has an interesting hidden geometrical construction that is based on a circle centred at the fingertips of Christ discovered by B. A. R. Carter²³. This circle, representing God, passes through the vertices of an equilateral triangle whose upper horizontal side cuts through the hovering dove representing the Holy Spirit, and whose vertices are placed at the upper corners of the rectangular main part of the painting and the right foot of Christ. If a circular arc centered at the foot of Christ is now drawn through his eyes, the length of its radius enables a regular pentagon to be drawn with vertices on the original circle, whose five angles of 72^o each at the centre are related to the golden section which is discussed in Appendix A and which will also be of interest later on in the next section in connection with nonperiodic tiling.

 

To show how Piero della Francesca could have constructed a regular pentagon using just a straight edge and a compass, consider a right-angled triangle having the base side of length a and the vertical side of length b = 2a. The hypotenuse c of this triangle has length (Ö5)a by the theorem of Pythagoras c² = a² + b², and can therefore be drawn using only a straight edge and a compass, from which a length b = (Ö5 + 1)a/2 can then be marked out using a compass. Now the isosceles triangle ABC having two equal sides AB and AC of length b and a base BC of length a displayed in Fig. 2, where g = b/a is the golden section ratio, can be constructed using a straight edge and compass.

 

Fig. 2

 

Taking a circle of radius b centred at the fingertips of Christ situated at O, ten lines of lengths a forming a regular decagon subtending angles of 36⁰ at the centre can be marked out on the circle with only a compass and a straight edge. Then, as required, five lines forming a regular pentagon and subtending angles of 72⁰ at the centre can be marked out on the circle as depicted in Fig. 3.

 

Fig. 3

 

Symmetry in its various forms is rather pervasive in most aspects of art. It can be illustrated very well by reference to the work of John Ruskin²⁴ (1819-1900) and in particular his remarkable set of three volumes entitled The Stones of Venice published in 1851 that describes the architecture of Venice and explains his deep interest in the philosophy of art. They contain his beautiful drawing of a spandril decoration from the Ducal Palace possessing reflection symmetries with colour reversal about the vertical and horizontal axes as well as the two bisecting diagonals, and without colour reversal about the other four alternate axes, and an eightfold rotation symmetry without colour reversal and a sixteenfold rotation symmetry with colour reversal.

 

Spirals

 

We have already pointed out that Dürer in the first volume of his treatise Underweysung der Messung on geometry discussed the subject of spiral curves.

 

Spirals occur in many forms in nature. Examples are the forms of sea-shells such as the ammonite of the lower Jurassic period of the Mesozoic known only as fossils²⁸, the nautilus and the gastropods, and snail-shells, all of which do not change their spiral shape as they grow in size but just increase the number of their chambers, and the spiral horns of animals such as the rhinoceros, sheep and goat. Also some climbing plants such as the well known convolvulus weed spiral upwards, approximately in the form of a circular helix, along their supporting plants. Some, such as the convolvulus, spiral in the right-hand sense while others, such as the hop, spiral in the left-hand sense.

 

In architecture spirals are used, for example, in the staircases of buildings, a truly beautiful example being the Scala del Bovolo of the Palazzo Contarini in Venice.

 

Another interesting example is the open staircase in the Chateau de Blois close to Cloux at Ambois near the river Loire where Leonardo da Vinci spent his last days as an advisor to Francois I, King of France. An attractive example of a modern spiral staircase in England can be seen in the De La Warr Pavilion, a community centre as well as an arts centre having a theatre on the Bexhill sea front in East Sussex, which was designed by Erich Mendelsohn and opened in 1935.

 

Appendix B provides a short discussion of some aspects of the mathematics of spirals, including the equiangular spiral, which shows a striking resemblance to the form of the nautilus shell, the Cornu double spiral that is of importance in connection with the theory of the diffraction of light, and the circular helix.

 

 

5. MODERN ART

 

 

Much of the recent modern art of Western Europe is rather chaotic and seemingly irrational at first sight, possessing a non-objective dream-like, surrealistic, mystical and metaphysical quality with no obvious geometrical structure although closer inspection often reveals an underlying pattern. This modern art seems more concerned with communicating the inner unconscious feelings and emotions of the artist rather than with an accurate description of the external world and thus apparently little to do with mathematics. Occasionally even an element of sheer chance has been deliberately introduced into the structure of the artwork. Some of the renowned artists whose work displayed many of these characteristics were Hans Arp (1887-1966), Max Ernst (1891-1976), Marc Chagall (1887-1985), Joan Miro (1893-1983), Wassily Kandinsky (1866-1944, Salvador Dali (1904-1989) and Paul Klee (1879-1940). In fact Kandinsky said that 'One thing became clear to me: that objectiveness, the depiction of objects, needed no place in my paintings, and was indeed harmful to them.' But he also wrote: 'The final abstract expression of every art is number' and so he must have believed in an underlying, perhaps intuitive, mathematical foundation for art.²⁹

 

Influence of Cézanne and Picasso

 

Although Wassily Kandinsky, Paul Klee and many of their contemporaries created art that was non-objective and metaphysical, it is acknowledged that the French painter Paul Cézanne (1839-1906) had a most important and fundamental influence on modern art. His numerous paintings of La Montagne Sainte Victoire have shown his fascination with the roughly pyramidal shape of the mountain fashioned by erosion resulting from the action of the wind, rain and ice over long epochs of geological time. Another painting of Cézanne's exhibiting his interest in solid shapes is The Bathers in the National Gallery London where he has painted the bodies and limbs of the female bathers with decidedly emphasised cylindrical forms. In a famous letter to the painter Emile Bernard he wrote: “traiter la nature par le cylindre, la sphere, le cone, le tout mis en perspective...” which suggests that he thought that art should be based, at least to some extent, on solid geometry. This may have led unintentionally to the cubist movement as exemplified by the painting Portrait of Ambroise Vollard (1909-10) by Pablo Picasso (1881-1973) and the painting Young Girl with Guitar (1913) by George Braque (1882-1963) in which the subjects are fragmented into straight-edged triangular- and rectangular-like pieces with curved lines mostly excluded.

 

This movement based on three-dimensional geometrical considerations did not survive for any great length of time but it did lead subsequently to non-objective art. Thus Picasso and those who followed him, deliberately introduced non-symmetrical fantastic features into their paintings in order to emphasize some of the irregularities of nature, to exhibit pathos and to shock the viewer. Actually their clear feeling at that time was that the geometry of linear perspective is very restrictive and in order to describe the multi-dimensional character of a subject it was necessary to depart from straightforward symmetry. This can be observed in several of the paintings by Picasso such as the Weeping Woman or ‘Femme en Pleurs’ (1937), the Seated Woman (1938), and the Woman in a Blue Dress (1941) in which the faces of the women are seen from two different perspectives. However even the artist Henri Matisse (1869-1954) who remarked that L'exactitude n'est pas la verité and was a member of the group known as the Fauves or wild beasts, used perspective in a roughly conventional way as found in the painting Studio under the Eaves, where the vanishing point is clearly situated in the sunlit open window of the dark studio. The use of perspective is obviously necessary if any artist is to be able to depict the real objective world in any kind of credible fashion. In addition Matisse possessed a wonderful sense of the beauty of symmetry as can be seen from his lovely colourful painting Lady in Blue.

 

It is worth remembering here that in the painting Three Miracles of Saint Zenobius by Botticelli the events depicted take place at different times, and this is akin to avoiding single point perspective by introducing elements taken from different viewpoints in three-dimensional space although this may appear very peculiar and unrealistic as in the paintings of women by Picasso.

 

Picasso was a highly versatile worker with a prodigious output who possessed great ability as a graphic artist some of which he expressed in a neo-classical style characterized by the choice of a quite realistic form into which he introduced a non-rational and strange mystical quality. This was done, for example, by the transposition, dislocation and metamorphosis of parts of the human body such as the face and the eyes, and the use of symbolism to represent various ideas and thus entering a world of fantasy where normal geometrical relationships are absent.

 

An important artist who was also strongly influenced by the work of Picasso, and in particular the cubist movement, was Piet Mondrian (1872-1944) who developed an abstract but objective art form sometimes based on coloured geometrical shapes such as rectangles, an example being Composition with Red, Yellow and Blue. He used the metaphysical phrase 'plastic mathematics' introduced by the Dutch philosopher M. H. J. Schoenmaekers to describe his art. Schoenmaekers also used the phrase 'positive mysticism' to characterize his philosophical vision of Neo-plasticism which, like the strictly geometrical art of Islam, attempts to picture the character and structure of the universe although in a considerably less precise way.

 

Some modern art gives the appearance of being really chaotic, an example being the so-called 'action painting' carried out by the American artist Jackson Pollock (1912-56) characterized by turbulence and great agitation and to which it is rather difficult to ascribe any geometrical design.

 

There are a number of interesting modern exceptions to the surrealistic approach of Picasso and his followers including the group known as Op Artists doing so-called optical art beginning with the work of the Hungarian artist Victor Vasarely (b. 1908). An example of his art is Metagalaxy (1959) involving a twofold rotation that produces colour reversal between black and white. Another Op Artist is the American artist Richard Anuszkiewicz (b. 1930) whose Division of Intensity (1964) has a symmetry which involves invariance with respect to vertical and horizontal reflections.

 

Some of the earlier work of the British artist Bridget Riley (b. 1931) gives the impression of being founded on mathematical ideas since her early works done in black and white are composed of lines and curves, an example being Twist. Indeed a few of her recent paintings in colour retain the appearence of being based on patterns with a flavour of geometrical symmetry. However there is also some true computer art actually based on mathematical curves such as straight lines, circles, and spirals. An interesting pattern possessing a reflection symmetry about a vertical line through the centre, created by using combinations of sines and cosines to shape curves, is Entwined Hearts illustrated in Fig. 4.

 

 

 

Fig. 4. Entwined Hearts

 

Graphic Work of Escher

 

The most remarkable example of modern art having a strong mathematical basis is the entirely secular work of the Dutch artist Maurits Escher whose beautiful graphic work^2,14,17,25 has a very close connection with the religious art of Islam which I was concerned with earlier in section 3. His art takes the form of the regular close filling of a plane with repeating patterns of geometrical figures and involves symmetries associated with various mathematical transformations such as translations, reflections in a line producing mirror images, and rotations about points which may be twofold, fourfold, threefold or sixfold, producing lovely visual effects. For example, his picture of starfishes, clams and shells has fourfold rotation points where four starfishes and four snail shells meet and twofold symmetry points where clams meet. In the standard symbolic notation of crystallography given in Table 3 of section 2 the fourfold symmetry pattern is denoted by p4.

 

Escher also makes use of glide reflections, that is a translation or glide in a given direction followed by a reflection in a line parallel to the direction of translation, and often the symmetries he employs involve colour transformations. In fact there are seventeen possible basic one-colour two-dimensional patterns that can be used to close fill a plane by repetition as in a wallpaper or a tessellation, and forty-six two-colour two-dimensional patterns.

 

The one-colour two-dimensional patterns were first listed by the Russian crystallographer Fedorov in 1891 and have already been given, together with their crystallographic symbols, in Table 3 displayed in section 1 on Primitive Art.

 

Whereas the geometrical shapes used by the artists of Islam are mostly abstract, those used by Escher include birds, fishes, lizards, bats, insects such as bees and wasps, butterflies, flowers, shells, unicorns, horses as well as human figures^14,25.

 

To help understand his graphic work we shall discuss a number of his beautiful periodic drawings and connect their designs with the crystallographic symbolic notation associated with their characteristic symmetries.

 

We begin by considering one-colour designs classified according to Table 3.

 

Firstly, Escher’s drawing of light and dark geese is generated by two independent translations and has the symmetry pattern p1. A careful inspection shows that the shapes of the light geese and the dark geese are slightly different. The drawing is composed of a lattice of unit cells that are congruent parallelograms and enclose the basic pattern of the design. An example of a unit cell in this design is the parallelogram formed from the straight lines joining the tips of the beaks of four neighbouring light geese. Alternatively we could use the tips of the beaks of four adjacent dark geese. The drawing is then constructed from translations of this unit cell so as to entirely cover the whole picture.

 

Next, his drawing of birds and fishes has twofold rotation points where (i) heads of birds meet, (ii) tails of birds meet, (iii) right wings or left wings of birds meet. This has the symmetry pattern p2.

 

As an example of the symmetry pattern pg we have his design composed of a white man and a black man. There are rows of white men facing in opposite directions separated by rows of black men facing in opposite directions so that the unit cell is composed of two white men and two black men. By translating a row of men in the vertical direction and carrying out a reflection in a parallel mirror line it can be transformed into the row of men of the same colour facing in the opposite direction. This is a glide reflection denoted by the symbol g.

 

His picture of flies, falcons, bats and butterflies, with two sets of perpendicular mirror lines and twofold rotation points where the mirror lines intersect has the symmetry pattern pmm.

 

Next his picture of bees and wasps has a threefold symmetry pattern denoted by p31m. There are threefold points where the abdomens of the insects meet and where the legs of the insects meet. There are three sets of glide lines in this design.

 

His picture of bats and two other creatures also has a threefold symmetry pattern but now denoted by p3m1. The threefold rotation points occur where the heads, or tails, of the creatures meet. Mirror lines pass through these rotation points. Also there are three sets of glide lines in this pattern.

 

We next consider two-colour symmetry patterns designed by Escher.

 

Our first example is of black and white horsemen. Here black horsemen are converted into white horsemen by a vertical colour glide transformation. A horizontal translation converts white horsemen into white horsemen and black horsemen into black horsemen. This picture of horsemen has the two-colour symmetry pg/p1.

 

Our second example is of black and white beetles. Here vertical mirror lines transform black beetles into black beetles and white beetles into white beetles. Translations in the vertical direction also transform white beetles into each other and black beetles into each other. Black beetles are transformed into white beetles by a glide reflection, the colour glide line being parallel to neighbouring mirror lines and halfway between them. This picture of beetles has the two-colour symmetry cm/pm.

 

We next consider some fascinating examples of polychromatic symmetry using three or four colours.

 

His picture of unicorns coloured in red, yellow and green has vertical glide symmetry lines that transform unicorns facing in one direction into unicorns facing in the opposite direction. Also vertical translations transform unicorns from one colour into another colour. This picture of unicorns has a pg/pg three-colour symmetry pattern.

 

Further Escher’s picture of lizards involving a sixfold rotation symmetry with three colours, namely white, red and black has seventeen twofold points. There are twofold points between the tail ends of two lizards of the same colour. There are threefold rotation points where the right rear legs of the lizards meet and there are sixfold rotation points where the left front legs of the lizards meet transforming their colours from white to red to black by rotations through 60⁰. This picture of lizards has a p6/p2 three-colour symmetry pattern.

 

Also his picture of red, black and grey tadpoles has mirror lines in the vertical direction and along the lines making angles of 60⁰ with the vertical. Translations along these lines transform red into black into grey tadpoles. There are threefold points where the heads of the tadpoles meet and there are colour-threefold points where the legs of the tadpoles meet. In addition there are glide lines present in this design. This picture of tadpoles has a p31m/p3m1 three-colour symmetry pattern.

 

Escher was fascinated by mathematics and indeed said that “although I lack any training or knowledge in the exact sciences, I often feel closer to mathematicians than to my fellow artists”. Some of his art is concerned with going to infinity and involves representations of Lobachevskian or hyperbolic non-Euclidean geometries inside a circle using, for example, alternating fishes along circular arcs called Circle Limit III, and interlocking angels and devils called Circle Limit IV.

 

In Euclidean geometry, if a straight line L is chosen then, for any given point P which is not on this line, there is just one straight line L’ passing through P, in the plane of L and P, which does not meet L. The lines L’ and L are said to be parallel. However in a hyperbolic geometry, there is more than one line passing through P, in the plane of L and P, which does not meet the line L. Lobachevsky (1793-1856), together with Gauss (1777-1855) and Bolyai (1775-1856), were the first mathematicians to introduce non-Euclidean geometry. Lobachevsky's work was published first in 1829-30 but was written in Russian and was only noticed by a few people.

 

The model of hyperbolic geometry that Escher used in his Circle Limit designs was that introduced by the French mathematician Henri Poincare (1854-1912) in which all the hyperbolic points lie inside a bounding circle. The hyperbolic lines are arcs of circles that meet the bounding circle at right angles, with the inclusion of the straight lines that are diameters.

 

Escher had an interesting correspondence with the geometer H. S. M. Coxeter who greatly admired his artwork and often wrote about it^2,17.

 

Penrose Non-periodic Tessellations

 

Some time ago the Oxford theoretical physicist and mathematician Roger Penrose showed how two different tiles related by the golden section ratio g = 1.61803... may be used to completely fill a plane with an approximate fivefold rotational symmetry^26,27. One pair of such tiles is two rhombuses, one of which possesses internal angles of 72⁰ and 108⁰ while the other has internal angles of 36⁰ and 144⁰, shown in Figs. 5a and 5b.

 

 

Fig. 5a

 

 

Fig. 5b

 

 

 

Another pair of such tiles is the kite and the dart, also having internal angles of 72⁰ and 36⁰ that are shown in Figs. 6a, 6b, 6c. Interesting arrangements of these called the infinite sun pattern and the infinite star pattern can be constructed²⁷. These tiles have the angles 72⁰ and 36⁰ arising from the golden section discussed in Appendix A.

 

Fig. 6a

 

 

Fig. 6b Kite

 

Fig. 6c Dart

 

 

A plane cannot be completely filled using a repeating pattern having a true fivefold symmetry since it is mathematically impossible to do this using only regular pentagons as can be done with equilateral triangles, or squares, or regular hexagons, having common sides. An approximate fivefold symmetry analogous to the Penrose mosaic pattern has been found in materials known as quasicrystals. An example is shechtmanite, an alloy of magnesium, aluminium and zinc, which produces a quasicrystal composed of icosahedrons with 20 triangular faces having a fivefold symmetry.

 

Penrose nonperiodic tiling has been used for decorating walls and floors. The decagons, or polygons with ten sides, which are present throughout the Penrose mosaic pattern all have the same orientation²⁷.

 

Other tilings exhibiting interesting patterns have been created. An intriguing spiral tiling has been devised by Heinz Voderberg. It has two centres and is composed of nine-sided polygons, two of which combine into an octagon. Another interesting tessellation is composed of convex non-congruent heptagons.

 

Music

 

We have seen that much recent art has a transcendental, abstract and non-objective nature, unlike the tessellations we have considered above that have a decidedly mathematical basis. This has been mirrored in the composition of music in recent times. This may be said to have commenced with the music of Igor Stravinsky (1882-1971) and in particular with his composition Le Sacre du Printemps or The Rite of Spring dating from 1910-13, written even before the first world war of 1914-18, the Russian revolution and the rise of Nazism that destabilized European society to such a great extent. But although there are vivid dissonances in this music, which was described by Stravinsky's biographer Roman Vlad as brutal, savage, aggressive, and apparently chaotic, it has very distinctive rhythmic beats characterized by detailed structure and pattern and thus could be thought to have a kind of mathematical design. But disharmony is nothing especially new in music since the so-called Dissonance string quartet No. 19 in C major K.465 by Mozart begins with a discordant harmony that was once a topic of some debate. Haydn made the comment that if Mozart wrote the music in this way he must have had his own reasons for doing so. It is simply analogous to a slightly broken symmetry in a geometrical design.

 

 

6. EPILOGUE

 

 

Art is a visual means of communication which employs patterns, shapes and colours to convey emotions from within the artist and to describe the world without in a characteristically beautiful manner which produces pleasure in the observer or possibly shocks and perturbs him or her. It may be used to deliver a religious, social or political message, or to describe people, places or events, and to decorate buildings.

 

Art is not simply an accurate picture of a person or place. This can be achieved by just taking a straightforward photograph. It must always communicate something else. However this cannot be carried out without some underlying structure that is based on geometrical considerations or other mathematical principles although this may be quite intuitive. The mathematical basis does not have to be very explicit although in certain types of art it can be. For example fractals, and in particular those based on Mandelbrot sets, briefly discussed in Appendix C, can be used to create very weird and beautiful patterns composed of the points c in the complex plane which lead to bounded sequences derived from non-linear mappings such as z ® z² + c where z = x + iy is a complex number in which the square root of minus one i = Ö{-1} is an imaginary number and x, y are real numbers. However many would believe that, without some significant creative input from the unconscious mind of the mathematician programming the computer, patterns derived from Mandelbrot sets should not be regarded as true art.

 

It has been often emphasized before that symmetry plays an important role in art. One has only to examine the frescos painted by Michelangelo on the ceiling of the Sistine Chapel in Rome illustrating various scenes from Genesis in the Old Testament to see that they are arranged in a symmetrical, although cleverly broken, pattern and revel in the symmetry of the naked human form. Moreover the creation of Adam by God in the central panel exhibits a beautiful and revealing symmetrical relationship between God and his human creation. The forefinger of the right hand of God is pointing to the forefinger of the left hand of Adam. No combination of physical translations and rotations can transform Adam into God but a reflection in a mirror roughly parallel to their bodies through the point where the finger tips of God and Adam meet can achieve this in an approximate although, of course, not in an accurate way. Then Adam points with his right hand whereas God now points with his left hand. This suggests that Michelangelo is asserting that God created Adam not in his image but as a mirror image of himself. Also the creation of Eve from Adam has an interesting symmetrical pattern with Eve emerging along one diagonal and Adam lying approximately along the other diagonal together with four naked youths at the corners of the rectangular panel. The ancestors of Christ are symmetrically arranged in the eight triangular spandrels around the Sistine Chapel ceiling, with seven Prophets and five Sybils in between.

 

A partial deviation from symmetry is often needed to adequately express an artist's intentions or feelings. For example we may consider the painting by Dürer of Christ Among the Doctors in which there is a beautiful indication of a certain rotational symmetry in the hands of the young Christ and one of the wicked doctors who are in dispute²¹. It should not be surprising to us that Dürer wrote a treatise in 1525 on geometry entitled Underweysung der Messung or literally 'Instruction of Measurement'.

 

William Blake, despite his mysticism, understood symmetry very well as is evident from his poem “The Tyger” containing the words:

 

“What immortal hand and eye

Could frame thy fearful symmetry?”

 

and from his watercolours³⁰, for example 'The Ancient of Days' or 'God Creating the World' which is the frontispiece for Europe and illustrates A Prophecy:

 

“When he set a compass upon the face of the deep”

 

suggesting an intimate connection with geometry and the measurement of the universe. Here Elohim or God is depicted as an old man with a white beard given the name Urizen by Blake. Urizen, which may be a synonym for your reason and represents the dark oppressive rational side of the creator, is leaning forward with a compass from a radiant heavenly globe surrounded by clouds with his hair blowing in a cosmic or solar wind. There seems to be a similarity to the figure of Euclid in the painting named The School of Athens by Raphael in which he is also leaning down to take a measurement with a compass¹³. This painting has a strikingly symmetrical configuration with its vanishing point between the heads of Plato and Aristotle in the centre of the picture. It is well authenticated that William Blake held Raphael, as well as Dürer, in high esteem even as a youngster. Indeed he wrote that “I am happy I cannot say that Rafael Ever was from my Earliest Childhood hidden from Me”.

 

Although William Blake had a distinct apathy towards science, and in particular the supreme mathematician Isaac Newton who he also pictured looking downwards and holding a compass like the demonic Urizen who symbolises a creator who uses reason without imagination, many of his paintings display a great sense of symmetrical design and thus some relationship to geometry.

 

In the Palazzo Ducale in Urbino, Italy there is a very interesting and mysterious painting The Flagellation of Christ by Piero della Francesca. In this painting the perspective is so precise that it has been possible to construct an accurate three-dimensional physical model of the buildings and placement of the people in the picture, as has been shown by B. A. R. Carter²³.

 

The intricate design of the paving on the floor of the portico in this picture is not at all clear from a cursory view. However an analysis carried out by T. C. Czarnovski²³, shows that Christ is standing on a large circular black tile and that in the centre of the square foreground there is an eight-pointed star composed of white rhombus-shaped tiles surrounded by eight black square tiles. In addition there are four larger black square tiles in the corners, and at the edges there are four black triangular tiles as well as eight white irregular pentagonal shaped tiles. There is a similar design in the background.

 

Carter's model of The Flagellation of Christ shows a scene that may have a religious and historical significance but nevertheless is entirely imaginary and could never have occurred as depicted here.

 

On the other hand the model built by Philip Steadman based on the group of paintings by Jan Vermeer including The Music Lesson, is very likely a true construct using perspective of an actual room and its contents and people.

 

Just as a two-dimensional flat picture of a three-dimensional scene can lead to a three-dimensional construction of the scene, as in the previous example, our three-dimensional view of space, which necessarily involves a time dimension due to the finite speed of light, can lead to a four-dimensional space-time mathematical model of the universe. A major achievement of Einstein in his theory of relativity was the reinterpretation of dynamics and gravity in terms of a four-dimensional non-Euclidean space-time geometry as well as giving rise to mathematical cosmology. Thus we understand that Geometry, and indeed Mathematics generally, provides structure for both Science and Art.

 

Artists and musicians, like mathematicians and scientists, think and feel deeply about the structure of the world around them. Often they feel a mystical significance towards their art as did the modern artist Piet Mondrian with his use of the phrase 'plastic mathematics' to describe his art and its relation to the universe.

 

Obviously much modern art is objective. As an illustration we show the following indian ink drawing (Fig. 7) by the British war artist Daniel Moiseiwitsch in which a soldier in the second world war of 1939-45 is riding in a tram in the East-End of London. The tram rails, which take the role of the perspective lines in the drawing, approximately converge to the distant vanishing point, intimating the ultimate destiny of the soldier in the war. Other pictures by Daniel Moiseiwitsch can be viewed at the V & A in London.

 

 

Fig. 7. Soldier riding in a Tram in London

 

 

Earlier in this book, I drew attention to the connection between music and mathematics, in particular with regard to the Preludes and Fugues by Johann Sebastian Bach using the equal-temperament scale. In the book entitled Mozart The Man and his Works by W. J. Turner the author writes “One may speak often of a movement of Mozart just as a mathematician might speak of a beautiful proposition”. This is especially clear in the case of Mozart's last symphony K.551 in the key of C major known as the Jupiter. The Allegro molto fourth and last movement or finale, is written with incredible skill in a very complicated contrapuntal manner. Mozart uses five themes, three from the first-subject and two from the second-subject, that are made to combine harmoniously together in a way which can only be described as a miraculous mathematical skill, and which yet is intensely beautiful and moving as true art should be.

 

But there is an essential difference between music and pictorial art. Whereas music is an art form that depends on the flow of time, pictorial art as well as sculpture and architecture are transparently spatial in character and frozen in time. However the music written down by the composer on sheets of paper envisages the music as a single entity that can be read and relates progression in time with position in space. In fact the performer of a piece of music, for example for the piano, has to own the music, as has been said by the renowned pianist Artur Rubinstein, that is the artist has to endeavour to remember and also perform the music completely as a unified whole. It is noteworthy that the theory of relativity combines space and time together into a single geometrical space-time continuum and that this provides a remarkably accurate way of describing the universe at the macroscopic level.

 

Finally, it is noteworthy that so-called primitive art is strongly based on geometry and mathematical symmetry, as indeed is the religious art of Islam. As our knowledge of mathematics developed further during the early Renaissance and our understanding of the physical world improved, the use of perspective and geometry by the artists of that time in order to introduce more reality into their pictures became increasingly evident, and subsequently was used very successfully by many of the artists who followed them. It is therefore rather interesting that towards the end of the 19^th century and then in the 20th century, when the easy use of photography became widespread, a revolt against the straightforward use of perspective came about and non-objective art became fashionable. Nowadays it is still felt that depicting the real world accurately, as was done in the past, is much less important than giving full freedom to the expression of emotions and the unconscious mind. However there now seems to be developing a turn away from this attitude and some interest is being shown not only in the mathematical art of Escher but also in other modern artists concerned with objectivity who are once again wishing to describe the world in a reasonably accurate way based on considerations of geometry and symmetry.

 

 

APPENDIX A. GOLDEN SECTION

 

 

If a section of length a is chosen on a line of length b and we take

 

{b-a}/a = a/b

 

then a is the golden section of the line of length b. It follows that

 

(b/a)² - b/a – 1 = 0

 

and so, setting g = b/a, we obtain the quadratic equation

 

g² – g - 1 = 0

 

that has the positive solution

 

g = {1+Ö5}/2 = 1.61803...

 

Now consider the isosceles triangle ABC shown in Fig. 2 with equal sides AB and AC of length b and base BC of length a having the angle 36⁰ at the vertex A.

Then the equal angles at B and C are 72⁰. Next we construct an isosceles triangle BCD, where D is on the line AC, with equal sides BC and BD of length a, and angle 36⁰ at the vertex B. Then the angle ABD must be 36⁰ also and so ADB is an isosceles triangle with the length of the side AD being equal to the length a of the side BD. Hence DC has length b-a and so

 

(b-a)/(2a) = cos 72⁰

 

giving

 

b/a = 1 + 2cos 72⁰.

 

Also

 

b/a = 2cos 36⁰

 

and since, by the trigonometric formula cos 2q = 2cos² q - 1, we have

 

cos 72⁰ = 2cos² 36⁰ - 1,

 

we see that b/a satisfies the quadratic equation derived above for the golden section ratio g.

 

Thus the golden section ratio is given by

 

g = 1/{g - 1} = {1 + Ö5}/2 = 1 + 2cos 72⁰ = 2cos 36⁰ = 1.61803...

 

 

Fibonacci Numbers

 

The golden section is also related to the Fibonacci sequence of numbers

 

 

1,2,3,5,8,13,21,34,55,89,...

 

 

The nth number a_n of the sequence is obtained by adding the previous

two numbers a_n-1 and a_n-2 together giving:

 

a_n = a_n-1+a_n-2

 

which is a formula first stated by the astronomer Kepler although it must have been known to Leonardo Fibonacci (c.1170-1250), also called Leonardo of Pisa, who originally introduced his sequence of numbers to describe the rate at which rabbits would produce offspring if each pair gives birth to a new pair each month, which produce at the end of two months, and the rabbits live for ever.

 

Then we have

 

a_n/a_n-1 = 1 + a_n-2/a_n-1

 

and if we set f_n = a_n/a_n-1 we get

 

f_n = 1 + 1/f_n-1.

 

 

It follows from this result that f_n > 1 and

 

f_n+1 - f_n = -(f_n - f_n-1)/f_nf_n-1

 

so that f_n+1 - f_n has the opposite sign to f_n - f_n-1 and |f_n+1 - f_n| < |f_n - f_n-1|.

 

In fact we have f₂ = 2, f₃ = 3/2 = 1.5, f₄ = 5/3 = 1.66666..., f₅ = 8/5 = 1.6,  f₆ = 13/8 = 1.625, f₇ = 21/13 = 1.61538..., f₈ = 34/21 = 1.61904..., f₉ = 55/34 = 1.61764....

 

We now observe that the limiting value f of f_n as n ® ¥ satisfies the equation

 

f = 1 + 1/f

 

which yields the quadratic equation f² – f – 1 = 0 which is the same equation as that satisfied by the golden section ratio g. Thus the ratio f_n of two successive Fibonacci numbers approaches the golden section ratio as we proceed up the sequence. For example f₁₀ = 89/55 = 1.61818... is only slightly larger and f₁₁ = 144/89 = 1.61797... is only slightly smaller than

 

g = (1 + Ö5})/2 = 1.61803... .

 

 

APPENDIX B. SPIRAL CURVES

 

 

Gnomons and the Equiangular Spiral

 

A certain class of spiral curves can be related to the golden section discussed in Appendix A in the following way. Let us again consider the triangles shown in Fig. 2. The triangle BCD is similar to the triangle ABC since the angles CBD and BAC are equal and

 

AB/BC = BC/CD = CA/DB

 

that is a cyclic formula obtained by going once round the corresponding sides of the two triangles:

 

AB ® BC ® CA and BC ® CD ® DB.

 

The triangle ADB is called the gnomon to the triangle BCD. The gnomon has a very old history going back to Pythagoras, Euclid and Hero in ancient Greek times and perhaps also to ancient Egypt. When a gnomon is added to a certain geometrical shape such as a triangle or parallelogram the shape remains unaltered. Thus in the case of the isosceles triangles in Fig. 2, when the gnomon triangle ADB is added to the triangle BCD the similar triangle ABC is obtained. If we now construct a series of gnomons as shown in Fig. 8 the vertices A, B, C, D, E, F,  G,... of the successive gnomons lie on an equiangular or logarithmic spiral, that is a spiral whose tangent at any of its points makes the same angle a with the radius directed from the limiting point or centre of the spiral. If r is the radial distance from the centre to a given point of the spiral and q is the angle that the radius makes with a fixed line in the plane of the spiral, its equation takes the form

 

r = aexp lq

 

so that

 

ln (r/a) = lq

 

and the differential coefficient dr/dq is given by

 

dr/dq = lr

 

where l = cot a. Here ln denotes the natural logarithm to base e = 2.71828... and cot denotes the cotangent or the reciprocal of the tangent.

 

If we again refer to Fig. 8, where we have shown an equiangular spiral passing through the vertices of successive gnomons, it is interesting to note that the centre of the spiral is situated where the dashed lines meet. These are the straight line joining the vertex C to the mid-point of the opposite side AB of the triangle ABC and the straight line joining the vertex D to the mid-point of the opposite side BC of the similar triangle BCD and are called medians. All the other corresponding medians, such as the one from the vertex E to the mid-point of CD, also pass through the centre of the spiral. The appearance of the equiangular or logarithmic spiral in Fig. 8 is strikingly similar to the spiral shape of fossil nautilus shells²⁸.

Fig. 8. Gnomons and Equiangular Spiral

 

 

Cornu Double Spiral

 

The Cornu double spiral, introduced by the French physicist Cornu in 1874 to interpret the fringes produced by the diffraction of light by a rectangular slit in a screen, is displayed in Fig. 9. It looks somewhat like the double spirals found in the stone age art of 5000 years ago in the passage-grave situated in Newgrange. The parametric equations of the Cornu spiral are

,  

where x, y are the rectangular Cartesian coordinates of a point of the spiral curve and the end points of the double spiral shown in the figure occur at the upper limit value A = 5. One of the two limiting points of the double spiral occurs when

=, =,

and the other when x = y = -1/2. The integrals occurring here are known as Fresnel's integrals.

 

Fig. 9

 

The Cornu double spiral is invariant with respect to a twofold rotation about the origin. Although the Escher woodcut in three colours, Whirlpools, appears at first glance to be similar to the Cornu spiral, closer inspection shows that it involves a dual double spiral which is invariant with respect to a twofold rotation about the central point only if we ignore the colour reversal from red to grey and grey to red.

 

Circular Helix

 

A spiral staircase, such as the Scala del Bovolo, has the shape of a circular helix that has the same form as a string tightly wrapped around a circular cylinder in a spiral curve. It is given by the equations

 

x = acos q , y = asin q , z = bq

 

where x, y, z are rectangular Cartesian coordinates with the z axis chosen along the central axis of the cylinder, a is the radius of the cylinder, q is the angle of rotation about the axis and b is a constant which determines the rate of rotation. It can also be expressed in the alternative form

 

x² + y² = a², y/x = tan(z/b), z = bq .

 

 

Epicycles

 

The epicycles used by Ptolemy to interpret the motions of the planets in the night sky correspond to the uniform motion of a point P on a circle C₁ whose centre moves uniformly round a circle C₂ centred at the Earth. It has the flower-like shape displayed in Fig. 10 and is given by the Cartesian coordinates

 

x = x₁ + x₂, y = y₁ + y₂

 

where

 

 

x₁ = a₁cos(w₁t + e₁), x₂ = a₂cos(w₂t + e₂)

 

y₁ = a₁sin(w₁t + e₁), y₂ = a₂sin(w₂t + e₂)

 

 

Here t is the time, w₁ is the angular velocity, that is the rate of rotation, of P round the circle C₁ given by the equation x₁² + y₁² = a₁² and w₂ is the angular velocity of the centre of the circle C₁ round the circle C₂ given by the equation x₂² + y₂² = a₂².

 

 

Fig. 10 Epicycle

 

A closed curve results if w₁ is an integer multiple of w₂, that is w₁ = w₂n where the integer n-1 is the number of loops in the epicycle.

 

The particular epicycle curve having 8 loops shown in Fig. 10 was obtained by taking a₁ = 0.2, a₂ = 1, w₁ = 9, w₂ = 1, e₁ = e₂ = 0.

 

 

 

 

APPENDIX C. MANDELBROT SETS

 

 

 

Amazingly beautiful and wonderfully intricate patterns can be produced by selecting those points c for which a mapping such as z ® z² + c produces a bounded sequence. Such a set of points c is called a Mandelbrot set.

 

This mapping is characteristicaly non-linear since it depends on the square of z.

 

Here z and c are complex numbers. Thus we have

 

z = x + iy

 

where x and y are ordinary real numbers and the imaginary number i is the square root of -1, that is i = Ö{-1} so that i² = -1. The numbers z determine the position of points in the complex plane. The initial number z₀ is called the seed, and the n+1 th number of the sequence z_n+1 is given in terms of the n th number z_n by the formula

 

z_n+1 = z_n² + c

 

so that, for example, z₁ = z₀² + c.

 

Then the Mandelbrot set of numbers for this mapping are those complex numbers c for which there are sequences of complex numbers z_n which are bounded, that is they are confined within a finite region.

 

If we start the sequence with the number z₀ = 0 we obtain

 

z₁ = c, z₂ = c² + c, z₃ =(c² + c)² + c, z₄ = [(c² + c)² + c]² + c,

z₅ = {[(c² + c)² + c]² + c}² + c

 

and so on. For example if we take c = i we get the bounded sequence 0, i, -1 + i, -i, -1 + i, -i, ... but if we take c = 1 we get the unbounded sequence 0, 1, 2, 5, 26, 677, ... and so i belongs to the Mandelbrot set but 1 lies outside it.

 

However even if c is a member of the Mandelbrot set not all values of the seed z₀ may lead to a bounded sequence of numbers z_n. The boundary between those values of the seed z₀ that produce bounded sequences and unbounded sequences is called a Julia set and may have a very complicated structure.

 

Mandelbrot sets and Julia sets are examples of fractals which are characterized by having the same repetitive structure as one examines the set in closer and closer microscopic detail. This can be seen from a picture of a part of the Mandelbrot set, coloured black, in the complex plane shown in Fig. 11.

 

 

 

 

Fig. 11.

 

 

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