Mathematics and art

Mathematics in art: Albrecht Dürer's copper plate engraving Melencolia I, 1514. Mathematical references include a compass for geometry, a magic square and a truncated rhombohedron, while measurement is indicated by the scales and hourglass.[1]
Study of a vase as a solid of revolution by Paolo Uccello. 15th century

Mathematics and art are related in a variety of ways. Mathematics has itself been described as an art motivated by beauty. Mathematics can be discerned in arts such as music, dance, painting, architecture, sculpture, and textiles. This article focuses, however, on mathematics in the visual arts.

Mathematics and art have a long historical relationship. Artists have used mathematics since the 5th century BC when the Greek sculptor Polykleitos wrote his Canon, prescribing proportions based on the ratio 1:√2 for the ideal male nude. Persistent popular claims have been made for the use of the golden ratio in ancient art and architecture, without reliable evidence. In the Italian Renaissance, Luca Pacioli wrote the influential treatise De Divina Proportione (1509), illustrated with woodcuts by Leonardo da Vinci, on the use of the golden ratio in art. Another Italian painter, Piero della Francesca, developed Euclid's ideas on perspective in treatises such as De Prospectiva Pingendi, and in his paintings. The engraver Albrecht Dürer made many references to mathematics in his work Melencolia I. In modern times, the graphic artist M. C. Escher made intensive use of tessellation and hyperbolic geometry, with the help of the mathematician H. S. M. Coxeter, while the De Stijl movement led by Theo van Doesberg and Piet Mondrian explicitly embraced geometrical forms. Mathematics has inspired textile arts such as quilting, knitting, cross-stitch, crochet, embroidery, weaving, Turkish and other carpet-making, as well as kilim. In Islamic art, symmetries are evident in forms as varied as Persian girih and Moroccan zellige tilework, Mughal jaali pierced stone screens, and widespread muqarnas vaulting.

Mathematics has directly influenced art with conceptual tools such as linear perspective, the analysis of symmetry and mathematical objects such as polyhedra and the Möbius strip. Magnus Wenninger creates colourful stellated polyhedra, originally as models for teaching. Mathematical concepts such as recursion and logical paradox can be seen in paintings by Rene Magritte and in engravings by M. C. Escher, Computer art often makes use of fractals including the Mandelbrot set, and sometimes explores other mathematical objects such as cellular automata. Controversially, the artist David Hockney has argued that artists from the Renaissance onwards made use of the camera lucida to draw precise representations of scenes; the architect Philip Steadman similarly argued that Vermeer used the camera obscura in his distinctively observed paintings.

Other relationships include the algorithmic analysis of artworks by X-ray fluorescence spectroscopy, and stimuli to mathematics research, especially Filippo Brunelleschi's theory of perspective which eventually led to Girard Desargues's projective geometry. A persistent view, based ultimately on the Pythagorean notion of harmony in music, holds that everything was arranged by Number, that God is the geometer of the world, and that therefore the world's geometry is sacred, as seen in artworks such as William Blake's The Ancient of Days.

Origins: from Ancient Greece to the Renaissance

Polykleitos's Canon and symmetria

Roman copy in marble of Doryphoros, originally a bronze by Polykleitos
Further information: Polykleitos

Polykleitos the Elder (c.450–420 BCE) was a Greek sculptor from the school of Argos, and a contemporary of Phidias. His works and statues consisted mainly of bronze and were of athletes. According to the mathematician Xenocrates, Polykleitos is ranked as one of the most important sculptors of Classical antiquity for his work on the Doryphorus and the statue of Hera in the Heraion of Argos.[2] While his sculptures may not be as famous as those of Phidias, they are much admired. In the Canon of Polykleitos, a treatise he wrote designed to document the "perfect" anatomical proportions of the male nude, Polykleitos gives us a mathematical approach towards sculpturing the human body.[2]

Polykleitos uses the distal phalanx of the little finger as the basic module for determining the proportions of the human body.[3] Polykleitos multiplies the length of the distal phalanx by the square root of two (√2) to get the distance of the second phalanges and multiplies the length again by √2 to get the length of the third phalanges. Next, he takes the finger length and multiplies that by √2 to get the length of the palm from the base of the finger to the ulna. This geometric series of measurements progresses until Polykleitos has formed the arm, chest, body, and so on.[4]

The influence of the Canon of Polykleitos is immense in Classical Greek, Roman, and Renaissance sculpture, many sculptors following Polykleitos's prescription. While none of Polykleitos's original works survive, Roman copies demonstrate his ideal of physical perfection and mathematical precision. Some scholars argue that Pythagorean thought influenced the Canon of Polykleitos.[5] The Canon applies the basic mathematical concepts of Greek geometry, such as the ratio, proportion, and symmetria (Greek for "harmonious proportions") and turns it into a system capable of describing the human form through a series of continuous geometric progressions.[3]

Perspective and proportion

In classical times, rather than making distant figures smaller with linear perspective, painters sized objects and figures according to their thematic importance. In the Middle Ages, some artists used reverse perspective for special emphasis. The Muslim mathematician Alhazen (Ibn al-Haytham) described a theory of optics in his Book of Optics in 1021, but never applied it to art.[6] The Renaissance saw a rebirth of Classical Greek and Roman culture and ideas, among them the study of mathematics to understand nature and the arts. Two major motives drove artists in the late Middle Ages and the Renaissance towards mathematics. First, painters needed to figure out how to depict three-dimensional scenes on a two-dimensional canvas. Second, philosophers and artists alike were convinced that mathematics was the true essence of the physical world and that the entire universe, including the arts, could be explained in geometric terms.[7]

The rudiments of perspective arrived with Giotto (1266/7 – 1337), who attempted to draw in perspective using an algebraic method to determine the placement of distant lines. In 1415, the Italian architect Filippo Brunelleschi and his friend Leon Battista Alberti demonstrated the geometrical method of applying perspective in Florence, using similar triangles as formulated by Euclid, to find the apparent height of distant objects.[8][9] Brunelleschi's own perspective paintings are lost, but Masaccio's painting of the Holy Trinity shows his principles at work.[6][10][11]

Paolo Uccello made innovative use of perspective in The Battle of San Romano (c. 1435–1460).

The Italian painter Paolo Uccello (1397–1475) was fascinated by perspective, as shown in his paintings of The Battle of San Romano (c. 1435–1460): broken lances lie conveniently along perspective lines.[12][13]

The painter Piero della Francesca (c.1415–1492) exemplified this new shift in Italian Renaissance thinking. He was an expert mathematician and geometer, writing books on solid geometry and perspective, including De Prospectiva Pingendi (On Perspective for Painting), Trattato d'Abaco (Abacus Treatise), and De corporibus regularibus (Regular Solids).[14][15][16] The historian Vasari in his Lives of the Painters calls Piero the "greatest geometer of his time, or perhaps of any time."[17] Piero's interest in perspective can be seen in his paintings including the Polyptych of Perugia,[18] the San Agostino altarpiece and The Flagellation of Christ. His work on geometry influenced later mathematicians and artists including Luca Pacioli in his De Divina Proportione and Leonardo da Vinci. Piero studied classical mathematics and the works of Archimedes.[19] He was taught commercial arithmetic in "abacus schools"; his writings are formatted like abacus school textbooks,[20] perhaps including Leonardo Pisano (Fibonacci)'s 1202 Liber Abaci. Linear perspective was just being introduced into the artistic world. Leon Battista Alberti explained: "light rays travel in straight lines from points in the observed scene to the eye, forming a kind of pyramid with the eye as vertex." A painting constructed with linear perspective is a cross-section of that pyramid.[21]

In De Prospectiva Pingendi, Piero transforms his empirical observations of the way aspects of a figure change with point of view into mathematical proofs. His treatise starts in the vein of Euclid: he defines the point as "the tiniest thing that is possible for the eye to comprehend".[lower-alpha 1][7] He uses deductive logic to lead the reader to the perspective representation of a three-dimensional body.[22]

The artist David Hockney argued in his book Secret Knowledge: Rediscovering the Lost Techniques of the Old Masters that artists started using a camera lucida from the 1420s, resulting in a sudden change in precision and realism, and that this practice was continued by major artists including Ingres, Van Eyck, and Caravaggio.[23] Critics disagree on whether Hockney was correct.[24][25] Similarly, the architect Philip Steadman argued controversially[26] that Vermeer had used a different device, the camera obscura, to help him create his distinctively observed paintings.[27]

In 1509, Luca Pacioli (c. 1447–1517) published De divina proportione on mathematical and artistic proportion, including in the human face. Leonardo da Vinci (1452–1519) illustrated the text with woodcuts of regular solids while he studied under Pacioli in the 1490s. Leonardo's drawings are probably the first illustrations of skeletonic solids.[28] These, such as the rhombicuboctahedron, were among the first to be drawn to demonstrate perspective by being overlaid on top of each other. The work discusses perspective in the works of Piero della Francesca, Melozzo da Forlì, and Marco Palmezzano.[29] Da Vinci studied Pacioli's Summa, from which he copied tables of proportions.[30] In Mona Lisa and The Last Supper, Da Vinci's work incorporated linear perspective with a vanishing point to provide apparent depth.[31] The Last Supper is constructed in a tight ratio of 12:6:4:3, as is Raphael's The School of Athens, which includes Pythagoras with a tablet of ideal ratios, sacred to the Pythagoreans.[32][33] In Vitruvian Man, Leonardo expressed the ideas of the Roman architect Vitruvius, innovatively showing the male figure twice, and centring him in both a circle and a square.[34]

As early as the 15th century, curvilinear perspective found its way into paintings by artists interested in image distortions. Jan van Eyck's 1434 Arnolfini Portrait contains a convex mirror with reflections of the people in the scene,[35] while Parmigianino's Self-portrait in a Convex Mirror, c. 1523–1524, shows the artist's largely undistorted face at the centre, with a strongly curved background and artist's hand around the edge.[36]

Three-dimensional space can be represented convincingly in art, as in technical drawing, by means other than perspective. Oblique projections, including cavalier perspective (used by French military artists to depict fortifications in the 18th century), were used continuously and ubiquitously by Chinese artists from the first or second centuries until the 18th century. The Chinese acquired the technique from India, which acquired it from Ancient Rome. Oblique projection is seen in Japanese art, such as in the Ukiyo-e paintings of Torii Kiyonaga (1752–1815).[37]

Golden ratio

The golden ratio, roughly equal to 1.618, was known to Euclid.[38] The golden ratio has persistently been claimed[39][40][41][42] in modern times to have been used in art and architecture by the ancients in Egypt, Greece and elsewhere, without reliable evidence.[43] The claim may derive from confusion with "golden mean", which to the Ancient Greeks meant "avoidance of excess in either direction", not a ratio.[43] Pyramidologists since the nineteenth century have argued on dubious mathematical grounds for the golden ratio in pyramid design.[lower-alpha 2] The 5th century BCE temple, the Parthenon in Athens, has been claimed to use the golden ratio in its façade and floor plan,[46][47][48] but these claims too are disproved by measurement.[43] The Great Mosque of Kairouan in Tunisia has similarly been claimed to use the golden ratio in its design,[49] but the ratio does not appear in the original parts of the mosque.[50] The historian of architecture Frederik Macody Lund argued in 1919 that the Cathedral of Chartres (12th century), Notre-Dame of Laon (1157–1205) and Notre Dame de Paris (1160) are designed according to the golden ratio,[51] drawing regulator lines to make his case. Other scholars argue that until Pacioli's work in 1509, the golden ratio was unknown to artists and architects.[52] For example, the height and width of the front of Notre-Dame of Laon have the ratio 8/5 or 1.6, not 1.618. Such Fibonacci ratios quickly become hard to distinguish from the golden ratio.[53] After Pacioli, the golden ratio is more definitely discernible in artworks including Leonardo's Mona Lisa.[54]

Planar symmetries

Powerful presence:[55] carpet with double medallion. Central Anatolia (Konya – Karapınar), turn of the 16th/17th centuries. Alaeddin Mosque

Planar symmetries have for millennia been exploited in artworks such as carpets, lattices, textiles and tilings.[56][57][58][59]

Many traditional rugs, whether pile carpets or flatweave kilims, are divided into a central field and a framing border; both can have symmetries, though in handwoven carpets these are often slightly broken by small details, variations of pattern and shifts in colour introduced by the weaver.[56] In kilims from Anatolia, the motifs used are themselves usually symmetrical. The general layout, too, is usually present, with arrangements such as stripes, stripes alternating with rows of motifs, and packed arrays of roughly hexagonal motifs. The field is commonly laid out as a wallpaper with a wallpaper group such as pmm, while the border may be laid out as a frieze of frieze group pm11, pmm2 or pma2. Turkish and Central Asian kilims often have three or more borders in different frieze groups. Weavers certainly had the intention of symmetry, without explicit knowledge of its mathematics.[56] The mathematician and architectural theorist Nikos Salingaros suggests that the "powerful presence"[55] (aesthetic effect) of a "great carpet"[55] such as the best Konya two-medallion carpets of the 17th century is created by mathematical techniques related to the theories of the architect Christopher Alexander. These techniques include making opposites couple; opposing colour values; differentiating areas geometrically, whether by using complementary shapes or balancing the directionality of sharp angles; providing small-scale complexity (from the knot level upwards) and both small- and large-scale symmetry; repeating elements at a hierarchy of different scales (with a ratio of about 2.7 from each level to the next). Salingaros argues that "all successful carpets satisfy at least nine of the above ten rules", and suggests that it might be possible to create a metric from these rules.[55]

Elaborate lattices are found in Indian Jaali work, carved in marble to adorn tombs and palaces.[57] Chinese lattices, always with some symmetry, exist in 14 of the 17 wallpaper groups; they often have mirror, double mirror, or rotational symmetry. Some have a central medallion, and some have a border in a frieze group.[60] Many Chinese lattices have been analysed mathematically by Daniel S. Dye; he identifies Sichuan as the centre of the craft.[61]

Symmetries are prominent in textile arts including quilting,[58] knitting,[62] cross-stitch, crochet,[63] embroidery[64][65] and weaving,[66] where they may be purely decorative or may be marks of status.[67] Rotational symmetry is found in circular structures such as domes; these are sometimes elaborately decorated with symmetric patterns inside and out, as at the 1619 Sheikh Lotfollah Mosque in Isfahan.[68] Items of embroidery and lace work such as tablecloths and table mats, made using bobbins or by tatting, can have a wide variety of reflectional and rotational symmetries which are being explored mathematically.[69]

Islamic art exploits symmetries in many of its artforms, notably in girih tilings. These are formed using a set of five tile shapes, namely a regular decagon, an elongated hexagon, a bow tie, a rhombus, and a regular pentagon. All the sides of these tiles have the same length; and all their angles are multiples of 36° (π/5 radians), offering fivefold and tenfold symmetries. The tiles are decorated with strapwork lines (girih), generally more visible than the tile boundaries. In 2007, the physicists Peter Lu and Paul Steinhardt argued that girih resembled quasicrystalline Penrose tilings.[70] Elaborate geometric zellige tilework is a distinctive element in Moroccan architecture.[59] Muqarnas vaults are three-dimensional but were designed in two dimensions with drawings of geometrical cells.[71]

  1. ^ Cite error: The named reference Gamwell423 was invoked but never defined (see the help page).

Polyhedra

The first printed illustration of a rhombicuboctahedron, by Leonardo da Vinci, published in De Divina Proportione, 1509

The Platonic solids and other polyhedra are a recurring theme in Western art. They are found, for instance, in a marble mosaic featuring the small stellated dodecahedron, attributed to Paolo Uccello, in the floor of the San Marco Basilica in Venice;[12] in Leonardo da Vinci's diagrams of regular polyhedra drawn as illustrations for Luca Pacioli's 1509 book The Divine Proportion;[12] as a glass rhombicuboctahedron in Jacopo de Barbari's portrait of Pacioli, painted in 1495;[12] in the truncated polyhedron (and various other mathematical objects) in Albrecht Dürer's engraving Melencolia I;[12] and in Salvador Dalí's painting The Last Supper in which Christ and his disciples are pictured inside a giant dodecahedron.

Albrecht Dürer (1471–1528) was a German Renaissance printmaker who made important contributions to polyhedral literature in his 1525 book, Underweysung der Messung (Education on Measurement), meant to teach the subjects of linear perspective, geometry in architecture, Platonic solids, and regular polygons. Dürer was likely influenced by the works of Luca Pacioli and Piero della Francesca during his trips to Italy.[72] While the examples of perspective in Underweysung der Messung are underdeveloped and contain inaccuracies, there is a detailed discussion of polyhedra. Dürer is also the first to introduce in text the idea of polyhedral nets, polyhedra unfolded to lie flat for printing.[73] Dürer published another influential book on human proportions called Vier Bücher von Menschlicher Proportion (Four Books on Human Proportion) in 1528.[74]

Dürer's well-known engraving Melencolia I depicts a frustrated thinker sitting by a truncated triangular trapezohedron and a magic square.[1] These two objects, and the engraving as a whole, have been the subject of more modern interpretation than the contents of almost any other print,[1][75][76] including a two-volume book by Peter-Klaus Schuster,[77] and an influential discussion in Erwin Panofsky's monograph of Dürer.[78][1] Salvador Dali's Corpus Hypercubus depicts an unfolded three-dimensional net for a hypercube, a four-dimensional regular polyhedron.[79]

A complex relationship

The astronomer Galileo Galilei in his Il Saggiatore wrote that "[The universe] is written in the language of mathematics, and its characters are triangles, circles, and other geometric figures."[80] Artists who strive and seek to study nature must first, in Galileo's view, fully understand mathematics. Mathematicians, conversely, have sought to interpret and analyse art through the lens of geometry and rationality. The mathematician Felipe Cucker suggests that mathematics, and especially geometry, is a source of rules for "rule-driven artistic creation", though not the only one.[81] Some of the many strands of the resulting complex relationship[82] are described below.

The mathematician G. H. Hardy defined a set of criteria for mathematical beauty.

Mathematics as an art

Main article: Mathematical beauty

The mathematician Jerry P. King describes mathematics as an art, stating that "the keys to mathematics are beauty and elegance and not dullness and technicality", and that beauty is the motivating force for mathematical research.[83] King cites the mathematician G. H. Hardy's 1940 essay A Mathematician's Apology. In it, Hardy discusses why he finds two theorems of classical times as first rate, namely Euclid's proof there are infinitely many prime numbers, and the proof that the square root of 2 is irrational. King evaluates this last against Hardy's criteria for mathematical elegance: "seriousness, depth, generality, unexpectedness, inevitability, and economy" (King's italics), and describes the proof as "aesthetically pleasing".[84] The Hungarian mathematician Paul Erdős agreed that mathematics possessed beauty but considered the reasons beyond explanation: "Why are numbers beautiful? It's like asking why is Beethoven's Ninth Symphony beautiful. If you don't see why, someone can't tell you. I know numbers are beautiful.[85]

Mathematical tools for art

Mathematics can be discerned in many of the arts, such as music, dance,[86] painting, architecture, and sculpture. Each of these is richly associated with mathematics.[87] Among the connections to the visual arts, mathematics can provide tools for artists, such as the rules of linear perspective as described by Brook Taylor and Johann Lambert, or the methods of descriptive geometry, now applied in software modelling of solids, dating back to Albrecht Dürer and Gaspard Monge.[88] Artists from Luca Pacioli in the Middle Ages and Leonardo da Vinci and Albrecht Dürer in the Renaissance have made use of and developed mathematical ideas in the pursuit of their artistic work.[87][89] The use of perspective began, despite some embryonic usages in the architecture of Ancient Greece, with Italian painters such as Giotto in the 13th century; rules such as the vanishing point were first formulated by Brunelleschi in about 1413,[6] his theory influencing Leonardo and Dürer. Isaac Newton's work on the optical spectrum influenced Goethe's Theory of Colours and in turn artists such as Philipp Otto Runge, J. M. W. Turner,[90] the Pre-Raphaelites and Wassily Kandinsky.[91][92] Artists may also choose to analyse the symmetry of a scene.[93] Tools may be applied by mathematicians who are exploring art, or artists inspired by mathematics, such as M. C. Escher (inspired by H. S. M. Coxeter) and the architect Frank Gehry, who more tenuously argued that computer aided design enabled him to express himself in a wholly new way.[94]

Octopod by Mikael Hvidtfeldt Christensen. Algorithmic art produced with the software Structure Synth

The artist Richard Wright argues that mathematical objects that can be constructed can be seen either "as processes to simulate phenomena" or as works of "computer art". He considers the nature of mathematical thought, observing that fractals were known to mathematicians for a century before they were recognised as such. Wright concludes by stating that it is appropriate to subject mathematical objects to any methods used to "come to terms with cultural artifacts like art, the tension between objectivity and subjectivity, their metaphorical meanings and the character of representational systems." He gives as instances an image from the Mandelbrot set, an image generated by a cellular automaton algorithm, and a computer-rendered image, and discusses, with reference to the Turing test, whether algorithmic products can be art.[95] Sasho Kalajdzievski's Math and Art: An Introduction to Visual Mathematics takes a similar approach, looking at suitably visual mathematics topics such as tilings, fractals and hyperbolic geometry.[96] Some of the first works of computer art were created by Desmond Paul Henry's "Drawing Machine 1", an analogue machine based on a bombsight computer and exhibited in 1962.[97][98] The machine was capable of creating complex, abstract, asymmetrical, curvilinear, but repetitive line drawings.[99][97] More recently, Hamid Naderi Yeganeh has created shapes suggestive of real world objects such as fish, using formulae that are successively varied to draw families of curves or angled lines.[100] Artists such as Mikael Hvidtfeldt Christensen create works of generative or algorithmic art by writing scripts for a software system such as Structure Synth: the artist effectively directs the system to apply a desired combination of mathematical operations to a chosen set of data.[101][102]

From mathematics to art

Proto-Cubism: Pablo Picasso's 1907 painting Les Demoiselles d'Avignon uses a fourth dimension projection to show a figure both full face and in profile.[103]

The mathematician and theoretical physicist Henri Poincaré's Science and Hypothesis was widely read by the Cubists, including Pablo Picasso and Jean Metzinger.[104][105] Poincaré viewed Euclidean geometry as just one of many possible geometric configurations, rather than as an absolute objective truth. The possible existence of a fourth dimension inspired artists to question classical Renaissance perspective: non-Euclidean geometry became a valid alternative.[106][107][108] The concept that painting could be expressed mathematically, in colour and form, contributed to Cubism, the art movement that led to abstract art.[109] Metzinger, in 1910, wrote of Princet: "[Picasso] lays out a free, mobile perspective, from which that ingenious mathematician Maurice Princet has deduced a whole geometry".[110] Later, Metzinger wrote in his memoirs:

Maurice Princet joined us often ... it was as an artist that he conceptualized mathematics, as an aesthetician that he invoked n-dimensional continuums. He loved to get the artists interested in the new views on space that had been opened up by Schlegel and some others. He succeeded at that.[111]

The impulse to make teaching or research models of mathematical forms naturally creates objects that have symmetries and surprising or pleasing shapes. Some of these have inspired artists such as the Dadaists Man Ray,[112] Marcel Duchamp[113] and Max Ernst,[114][115] and following Man Ray, Hiroshi Sugimoto.[116]

Enneper surfaces as Dadaism: Man Ray's 1934 Objet mathematique

Man Ray photographed some of the mathematical models in the Institut Henri Poincaré in Paris, including Objet mathematique (Mathematical object). He noted that this represented Enneper surfaces with constant negative curvature, derived from the pseudo-sphere. This mathematical foundation was important to him, as it allowed him to deny that the object was "abstract", instead claiming that it was as real as the urinal that Duchamp made into a work of art. Man Ray admitted that the object's [Enneper surface] formula "meant nothing to me, but the forms themselves were as varied and authentic as any in nature." He used his photographs of the mathematical models as figures in his series he did on Shakespeare's plays, such as his 1934 painting Antony and Cleopatra.[117] The art reporter Jonathan Keats, writing in ForbesLife, argues that Man Ray photographed "the elliptic paraboloids and conic points in the same sensual light as his pictures of Kiki de Montparnasse", and "ingeniously repurposes the cool calculations of mathematics to reveal the topology of desire".[118] Twentieth century sculptors such as Henry Moore, Barbara Hepworth and Naum Gabo took inspiration from mathematical models.[119] Moore wrote of his 1938 Stringed Mother and Child: "Undoubtedly the source of my stringed figures was the Science Museum ... I was fascinated by the mathematical models I saw there ... It wasn't the scientific study of these models but the ability to look through the strings as with a bird cage and to see one form within another which excited me."[120]

Theo van Doesburg's Six Moments in the Development of Plane to Space, 1926 or 1929

The artists Theo van Doesburg and Piet Mondrian founded the De Stijl movement, which they wanted to "establish a visual vocabulary comprised of elementary geometrical forms comprehensible by all and adaptable to any discipline".[121][122] Many of their artworks visibly consist of ruled squares and triangles, sometimes also with circles. De Stijl artists worked in painting, furniture, interior design and architecture.[121] After the breakup of De Stijl, Van Doesburg founded the Avant-garde Art Concret movement, describing his 1929–1930 Arithmetic Composition, a series of four black squares on the diagonal of a squared background, as "a structure that can be controlled, a definite surface without chance elements or individual caprice", yet "not lacking in spirit, not lacking the universal and not ... empty as there is everything which fits the internal rhythm". The art critic Gladys Fabre observes that two progressions are at work in the painting, namely the growing black squares and the alternating backgrounds.[123]

The mathematics of tessellation, polyhedra, shaping of space, and self-reference provided the graphic artist M. C. Escher (1898—1972) with a lifetime's worth of materials for his woodcuts.[124][125] In the Alhambra Sketch, Escher showed that art can be created with polygons or regular shapes such as triangles, squares, and hexagons. Escher used irregular polygons when tiling the plane and often used reflections, glide reflections, and translations to obtain further patterns. Many of his works contain impossible constructions, made using geometrical objects which set up a contradiction between perspective projection and three dimensions, but are pleasant to the human sight. Escher's Ascending and Descending is based on the "impossible staircase" created by the medical scientist Lionel Penrose and his son the mathematician Roger Penrose.[126][127][128]

Some of Escher's many tessellation drawings were inspired by conversations with the mathematician H. S. M. Coxeter on hyperbolic geometry.[129] Escher was especially interested in five specific polyhedra, which appear many times in his work. The Platonic solids—tetrahedrons, cubes, octahedrons, dodecahedrons, and icosahedrons—are especially prominent in Order and Chaos and Four Regular Solids.[130] These stellated figures often reside within another figure which further distorts the viewing angle and conformation of the polyhedrons and provides a multifaceted perspective artwork.[131]

The visual intricacy of mathematical structures such as tessellations and polyhedra have inspired a variety of mathematical artworks. Stewart Coffin makes polyhedral puzzles in rare and beautiful woods; George W. Hart works on the theory of polyhedra and sculpts objects inspired by them; Magnus Wenninger makes "especially beautiful" models of complex stellated polyhedra.[132]

The mathematics of topology has inspired several artists in modern times. The sculptor John Robinson (1935–2007) created works such as Gordian Knot and Bands of Friendship, displaying knot theory in polished bronze.[7] Other works by Robinson explore the topology of toruses. Genesis is based on Borromean rings – a set of three circles, no two of which link but in which the whole structure cannot be taken apart without breaking.[133] The sculptor Helaman Ferguson creates complex surfaces and other topological objects.[134] His works are visual representations of mathematical objects; The Eightfold Way is based on the projective special linear group PSL(2,7), a finite group of 168 elements.[135][136] The sculptor Bathsheba Grossman similarly bases her work on mathematical structures.[137][138]

A liberal arts inquiry project examines connections between mathematics and art through the Möbius strip, flexagons, origami and panorama photography.[139]

Mathematical objects including the Lorenz manifold and the hyperbolic plane have been crafted using fiber arts including crochet.[lower-alpha 3][141][142] The American weaver Ada Dietz wrote a 1949 monograph Algebraic Expressions in Handwoven Textiles, defining weaving patterns based on the expansion of multivariate polynomials.[143] The mathematician J. C. P. Miller used the Rule 90 cellular automaton to design tapestries depicting both trees and abstract patterns of triangles.[144] The "mathekniticians"[145] Pat Ashforth and Steve Plummer use knitted versions of mathematical objects such as hexaflexagons in their teaching, though their Menger sponge proved too troublesome to knit and was made of plastic canvas instead.[146][147] Their "mathghans" (Afghans for Schools) project introduced knitting into the British mathematics and technology curriculum.[148][149]

  1. ^ Jouffret, Esprit (1903). Traité élémentaire de géométrie à quatre dimensions et introduction à la géométrie à n dimensions (in French). Paris: Gauthier-Villars. OCLC 1445172. Retrieved 26 September 2015. 
  2. ^ Miller, Arthur I. (2001). Einstein, Picasso: Space, Time, and the Beauty That Causes Havoc. New York: Basic Books. p. 171. ISBN 0-465-01860-2. 
  3. ^ Seckel, Hélène (1994). "Anthology of Early Commentary on Les Demoiselles d'Avignon". In William Rubin, Hélène Seckel, and Judith Cousins. Les Demoiselles d'Avignon. New York: Museum of Modern Art. p. 264. ISBN 0-87070-162-2. 


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Illustrating mathematics

Front face of Giotto's Stefaneschi Triptych, 1320 illustrates recursion.
Detail of Cardinal Stefaneschi holding the triptych

Modelling is far from the only possible way to illustrate mathematical concepts. Giotto's Stefaneschi Triptych, 1320, illustrates recursion; the central panel of the triptych contains, lower left, the kneeling figure of Cardinal Stefaneschi, holding up the triptych as an offering.[150] Giorgio Chirico's metaphysical paintings such as his 1917 Great Metaphysical Interior explore the question of levels of representation in art by depicting paintings within his paintings.[151]

Art can exemplify logical paradoxes, as in some paintings by the surrealist René Magritte, which can be read as semiotic jokes about confusion between levels. In La condition humaine (1933), Magritte depicts an easel (on the real canvas), seamlessly supporting a view through a window which is framed by "real" curtains in the painting. Similarly, Escher's Print Gallery (1956) is a print which depicts a distorted city which contains a gallery which recursively contains the picture, and so ad infinitum.[152] Magritte made use of spheres and cuboids to distort reality in a different way, painting them alongside an assortment of houses in his 1931 Mental Arithmetic as if they were children's building blocks, but house-sized.[153] The Guardian observed that the "eerie toytown image" prophesied Modernism's usurpation of "cosy traditional forms", but also plays with the human tendency to seek patterns in nature.[154]

Diagram of the apparent paradox embodied in M. C. Escher's 1956 lithograph Print Gallery, as discussed by Douglas Hofstadter in his 1980 book Gödel, Escher, Bach

Salvador Dalí's last painting, The Swallow's Tail (1983), was part of a series inspired by René Thom's catastrophe theory.[155] The Spanish painter and sculptor Pablo Palazuelo (1916–2007) focused on the investigation of form. He developed a style that he described as the geometry of life and the geometry of all nature. Consisting of simple geometric shapes with detailed patterning and coloring, in works such as Angular I and Automnes, Palazuelo expressed himself in geometric transformations.[7]

Lithograph Print Gallery by M. C. Escher, 1956

Artists, however, do not necessarily take geometry literally. As Douglas Hofstadter writes in his 1980 reflection on human thought, Gödel, Escher, Bach, by way of (among other things) the mathematics of art: "The difference between an Escher drawing and non-Euclidean geometry is that in the latter, comprehensible interpretations can be found for the undefined terms, resulting in a comprehensible total system, whereas for the former, the end result is not reconcilable with one's conception of the world, no matter how long one stares at the pictures." Hofstadter discusses the seemingly paradoxical lithograph Print Gallery by M. C. Escher; it depicts a seaside town containing an art gallery which seems to contain a painting of the seaside town, there being a "strange loop, or tangled hierarchy" to the levels of reality in the image. The artist himself, Hofstadter observes, is not seen; his reality and his relation to the lithograph are not paradoxical.[156] The image's central void has also attracted the interest of mathematicians Bart de Smit and Hendrik Lenstra, who propose that it could contain a Droste effect copy of itself, rotated and shrunk; this would be a further illustration of recursion beyond that noted by Hofstadter.[157][158]

Analysis of art history

Algorithmic analysis of images of artworks, for example using X-ray fluorescence spectroscopy, can reveal information about art. Such techniques can uncover images in layers of paint later covered over by an artist; help art historians to visualize an artwork before it cracked or faded; help to tell a copy from an original, or distinguish the brushstroke style of a master from those of his apprentices.[159][160]

Max Ernst making Lissajous figures, New York, 1942

Jackson Pollock's drip painting style[161] has a definite fractal dimension;[162] among the artists who may have influenced Pollock's controlled chaos,[163] Max Ernst painted Lissajous figures directly by swinging a punctured bucket of paint over a canvas.[164]

The computer scientist Neil Dodgson investigated whether Bridget Riley's stripe paintings could be characterised mathematically, concluding that while separation distance could "provide some characterisation" and global entropy worked on some paintings, autocorrelation failed as Riley's patterns were irregular. Local entropy worked best, and correlated well with the description given by the art critic Robert Kudielka.[165]

The American mathematician George Birkhoff's 1933 Aesthetic Measure proposes a quantitative metric of the aesthetic quality of an artwork. It does not attempt to measure the connotations of a work, such as what a painting might mean, but is limited to the "elements of order" of a polygonal figure. Birkhoff first combines (as a sum) five such elements: whether there is a vertical axis of symmetry; whether there is optical equilibrium; how many rotational symmetries it has; how wallpaper-like the figure is; and whether there are unsatisfactory features such as having two vertices too close together. This metric, O, takes a value between −3 and 7. The second metric, C, counts elements of the figure, which for a polygon is the number of different straight lines containing at least one of its sides. Birkhoff then defines his aesthetic measure of an object's beauty as O/C. This can be interpreted as a balance between the pleasure looking at the object gives, and the amount of effort needed to take it in. Birkhoff's proposal has been criticized in various ways, not least for trying to put beauty in a formula, but he never claimed to have done that.[166]

Stimuli to mathematical research

Art has sometimes stimulated the development of mathematics, as when Brunelleschi's theory of perspective in architecture and painting started a cycle of research that led to the work of Brook Taylor and Johann Heinrich Lambert on the mathematical foundations of perspective drawing,[167] and ultimately to the mathematics of projective geometry of Girard Desargues and Jean-Victor Poncelet.[168]

The Japanese paper-folding art of origami has been reworked mathematically by Tomoko Fusé using modules, congruent pieces of paper such as squares, and making them into polyhedra or tilings.[169] Paper-folding was used in 1893 by T. Sundara Rao in his Geometric Exercises in Paper Folding to demonstrate geometrical proofs.[170] The mathematics of paper folding has been explored in Maekawa's theorem,[171] Kawasaki's theorem,[172] and the Huzita–Hatori axioms.[173]

  1. ^ The World of Geometric Toys, Origami Spring, August, 2007.

Illusion to Op art

Further information: Op art
The Fraser spiral illusion, named for Sir James Fraser who discovered it in 1908.

Optical illusions such as the Fraser spiral strikingly demonstrate limitations in human visual perception, creating what the art historian Ernst Gombrich called a "baffling trick." The black and white ropes that appear to form spirals are in fact concentric circles. The mid-twentieth century Op art or optical art style of painting and graphics exploited such effects to create the impression of movement and flashing or vibrating patterns seen in the work of artists such as Bridget Riley, Spyros Horemis,[174] and Victor Vasarely.[175]

Sacred geometry

Further information: Sacred geometry and Mathematics and music

A strand of art from Ancient Greece onwards sees God as the geometer of the world, and the world's geometry therefore as sacred. The belief that God created the universe according to a geometric plan has ancient origins. Plutarch attributed the belief to Plato, writing that "Plato said God geometrizes continually" (Convivialium disputationum, liber 8,2). This image has influenced Western thought ever since. The Platonic concept derived in its turn from a Pythagorean notion of harmony in music, where the notes were spaced in perfect proportions, corresponding to the lengths of the lyre's strings; indeed, the Pythagoreans held that everything was arranged by Number. In the same way, in Platonic thought, the regular or Platonic solids dictate the proportions found in nature, and in art.[176][177] A Mediaeval manuscript illustration may refer to a verse in the Old Testament: "When he established the heavens I was there: when he set a compass upon the face of the deep" (Proverbs 8:27), showing God drawing out the universe with a pair of compasses.[178] In 1596, the mathematical astronomer Johannes Kepler modelled the universe as a set of nested Platonic solids, determining the relative sizes of the orbits of the planets.[178] William Blake's Ancient of Days and his painting of the physicist Isaac Newton, naked and drawing with a compass, attempt to depict the contrast between the mathematically perfect spiritual world and the imperfect physical world,[179] as in a different way does Salvador Dali's 1954 Crucifixion (Corpus Hypercubus), which depicts the cross as a hypercube, representing the divine perspective with four dimensions rather than the usual three.[79] In Dali's The Sacrament of the Last Supper (1955) Christ and his disciples are pictured inside a giant dodecahedron.[180]

See also

Notes

  1. In Piero's Italian: "una costa tanto picholina quanto e possible ad ochio comprendere".
  2. The ratio of the slant height to half the base length is 1.619, less than 1% from the golden ratio, implying use of Kepler's triangle (face angle 51°49').[43][44] It is more likely that pyramids were made with the 3-4-5 triangle (face angle 53°8'), known from the Rhind Mathematical Papyrus; or with the triangle with base to hypotenuse ratio 1:4/π (face angle 51°50').[45]
  3. Images and videos of Hinke Osinga's crocheted Lorenz manifold reached international television news, as can be seen in the linked website.[140]

References

  1. 1 2 3 4 Ziegler, Günter M. (3 December 2014). "Dürer's polyhedron: 5 theories that explain Melencolia's crazy cube". The Guardian. Retrieved 27 October 2015.
  2. 1 2 Stewart, Andrew (November 1978). "Polykleitos of Argos," One Hundred Greek Sculptors: Their Careers and Extant Works". Journal of Hellenic Studies 98: 122–131. doi:10.2307/630196. JSTOR 630196.
  3. 1 2 Tobin, Richard (October 1975). "The Canon of Polykleitos". American Journal of Archaeology 79 (4): 307–321. doi:10.2307/503064.
  4. Lawton, Arthur J. (2013). "Pattern, Tradition and Innovation in Vernacular Architecture". Past 36. Retrieved 25 June 2015. The base figure is a square the length and width of the distal phalange of the little finger. Its diagonals rotated to one side transform the square to a 1 : √2 root rectangle. In Figure 5 this rectangular figure marks the width and length of the adjacent medial phalange. Rotating the medial diagonal proportions the proximal phalange and similarly from there to the wrist, from wrist to elbow and from elbow to shoulder top. Each new step advances the diagonal's pivot point.
  5. Raven, J. E. (1951). "Polyclitus and Pythagoreanism". Classical Quarterly 1 (3–4): 147–. doi:10.1017/s0009838800004122.
  6. 1 2 3 O'Connor, J. J.; Robertson, E. F. (January 2003). "Mathematics and art – perspective". University of St Andrews. Retrieved 1 September 2015.
  7. 1 2 3 4 Emmer, Michelle, ed. (2005). The Visual Mind II. MIT Press. ISBN 978-0-262-05048-7.
  8. Vasari, Giorgio (1550). Lives of the Artists. Torrentino. p. Chapter on Brunelleschi.
  9. Alberti, Leon Battista; Spencer, John R. (1956) [1435]. On Painting. Yale University Press.
  10. Field, J. V. (1997). The Invention of Infinity: Mathematics and Art in the Renaissance. Oxford University Press. ISBN 978-0-19-852394-9.
  11. Witcombe, Christopher L. C. E. "Art History Resources". Retrieved 5 September 2015.
  12. 1 2 3 4 5 Hart, George W. "Polyhedra in Art". Retrieved 24 June 2015.
  13. Cunningham, Lawrence; Reich, John; Fichner-Rathus, Lois (1 January 2014). Culture and Values: A Survey of the Western Humanities. Cengage Learning. p. 375. ISBN 978-1-285-44932-6. which illustrate Uccello's fascination with perspective. The jousting combatants engage on a battlefield littered with broken lances that have fallen in a near-grid pattern and are aimed toward a vanishing point somewhere in the distance.
  14. della Francesca, Piero (1942) [c. 1474]. G. Nicco Fasola, ed. De Prospectiva Pingendi. Florence.
  15. della Francesca, Piero (1970) [Fifteenth century]. G. Arrighi, ed. Trattato d'Abaco. Pisa.
  16. della Francesca, Piero (1916). G. Mancini, ed. L'opera "De corporibus regularibus" di Pietro Franceschi detto della Francesca usurpata da Fra Luca Pacioli.
  17. Vasari, G. (1878). G. Milanesi, ed. Le Opere, volume 2. p. 490.
  18. Zuffi, Stefano (1991). Piero della Francesca. L'Unità – Mondadori Arte. p. 53.
  19. Heath, T.L. (1908). The Thirteen Books of Euclid's Elements. Cambridge University Press. p. 97.
  20. Grendler, P. (1995). M.A. Lavin, ed. What Piero Learned in School: Fifteenth-Century Vernacular Education. Piero della Francesca and His Legacy (University Press of New England). pp. 161–176.
  21. Alberti, Leon Battista; Grayson, Cecil (trans.) (1991). Kemp, Martin, ed. On Painting. Penguin Classics.
  22. Peterson, Mark. "The Geometry of Piero della Francesca". In Book I, after some elementary constructions to introduce the idea of the apparent size of an object being actually its angle subtended at the eye, and referring to Euclid's Elements Books I and VI, and Euclid's Optics, he turns, in Proposition 13, to the representation of a square lying flat on the ground in front of the viewer. What should the artist actually draw? After this, objects are constructed in the square (tilings, for example, to represent a tiled floor), and corresponding objects are constructed in perspective; in Book II prisms are erected over these planar objects, to represent houses, columns, etc.; but the basis of the method is the original square, from which everything else follows.
  23. Hockney, David (2006). Secret Knowledge: Rediscovering the Lost Techniques of the Old Masters. Thames and Hudson. ISBN 978-0-500-28638-8.
  24. Van Riper, Frank. "Hockney's 'Lucid' Bomb At the Art Establishment". The Washington Post. Retrieved 4 September 2015.
  25. Marr, Andrew (7 October 2001). "What the eye didn't see". The Guardian. Retrieved 4 September 2015.
  26. Janson, Jonathan (25 April 2003). "An Interview with Philip Steadman". Essential Vermeer. Retrieved 5 September 2015.
  27. Steadman, Philip (2002). Vermeer's Camera: Uncovering the Truth Behind the Masterpieces. Oxford. ISBN 978-0-19-280302-3.
  28. Hart, George. "Luca Pacioli's Polyhedra". Retrieved 13 August 2009.
  29. Morris, Roderick Conway (27 January 2006). "Palmezzano's Renaissance:From shadows, painter emerges". New York Times. Retrieved 22 July 2015.
  30. Calter, Paul. "Geometry and Art Unit 1". Dartmouth College. Retrieved 13 August 2009.
  31. Brizio, Anna Maria (1980). Leonardo the Artist. McGraw-Hill.
  32. Ladwein, Michael (2006). Leonardo Da Vinci, the Last Supper: A Cosmic Drama and an Act of Redemption. Temple Lodge Publishing. pp. 61–62. ISBN 978-1-902636-75-7.
  33. Turner, Richard A. (1992). Inventing Leonardo. Alfred A. Knopf.
  34. Wolchover, Natalie (31 January 2012). "Did Leonardo da Vinci copy his famous 'Vitruvian Man'?". NBC News. Retrieved 27 October 2015.
  35. Criminisi, A.; Kempz, M.; Kang, S. B. (2004). "Reflections of Reality in Jan van Eyck and Robert Campin" (PDF). Historical Methods 37 (3): 109–121. doi:10.3200/hmts.37.3.109-122.
  36. Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. pp. 299–300, 306–307. ISBN 978-0-521-72876-8.
  37. Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. pp. 269–278. ISBN 978-0-521-72876-8.
  38. Joyce, David E. (1996). "Euclid's Elements, Book II, Proposition 11". Clark University. Retrieved 24 September 2015.
  39. Seghers, M. J.; Longacre, J. J.; Destefano, G. A. (1964). "The Golden Proportion and Beauty". Plastic and Reconstructive Surgery 34 (4): 382–386. doi:10.1097/00006534-196410000-00007.
  40. Mainzer, Klaus (1996). Symmetries of Nature: A Handbook for Philosophy of Nature and Science. Walter de Gruyter. p. 118.
  41. "Mathematical properties in ancient theatres and amphitheatres". Retrieved 29 January 2014.
  42. "Architecture: Ellipse?". The-Colosseum.net. Retrieved 29 January 2014.
  43. 1 2 3 4 Markowsky, George (January 1992). "Misconceptions about the Golden Ratio" (PDF). The College Mathematics Journal 23 (1): 2–19. doi:10.2307/2686193.
  44. Taseos, Socrates G. (1990). Back in Time 3104 B.C. to the Great Pyramid. SOC Publishers.
  45. Gazale, Midhat (1999). Gnomon: From Pharaohs to Fractals. Princeton University Press. ISBN 978-0-691-00514-0.
  46. Huntley, H.E. (1970). The Divine Proportion. Dover.
  47. Hemenway, Priya (2005). Divine Proportion: Phi In Art, Nature, and Science. Sterling. p. 96.
  48. Usvat, Liliana. "Mathematics of the Parthenon". Mathematics Magazine. Retrieved 24 June 2015.
  49. Boussora, Kenza; Mazouz, Said (Spring 2004). "The Use of the Golden Section in the Great Mosque of Kairouan". Nexus Network Journal 6 (1): 7–16. doi:10.1007/s00004-004-0002-y. The geometric technique of construction of the golden section seems to have determined the major decisions of the spatial organisation. The golden section appears repeatedly in some part of the building measurements. It is found in the overall proportion of the plan and in the dimensioning of the prayer space, the court and the minaret. The existence of the golden section in some parts of Kairouan mosque indicates that the elements designed and generated with this principle may have been realised at the same period.
  50. Brinkworth, Peter; Scott, Paul (2001). "The Place of Mathematics". Australian Mathematics Teacher 57 (3): 2.
  51. Chanfón Olmos, Carlos (1991). Curso sobre Proporción. Procedimientos reguladors en construcción. Convenio de intercambio Unam–Uady. México – Mérica.
  52. Livio, Mario (2002). The Golden Ratio: The Story of Phi, The World's Most Astonishing Number. Broadway Books.
  53. Smith, Norman A. F. (2001). "Cathedral Studies: Engineering or History" (PDF). Transactions of the Newcomen Society 73: 95–137. doi:10.1179/tns.2001.005.
  54. McVeigh, Karen (28 December 2009). "Why golden ratio pleases the eye: US academic says he knows art secret". The Guardian. Retrieved 27 October 2015.
  55. 1 2 3 4 Salingaros, Nikos (November 1996). "The 'life' of a carpet: an application of the Alexander rules". 8th International Conference on Oriental Carpets (Philadelphia). Reprinted in Eiland, M.; Pinner, M., eds. (1998). Oriental Carpet and Textile Studies V. Danville, CA: Conference on Oriental Carpets.
  56. 1 2 3 Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. pp. 89–102. ISBN 978-0-521-72876-8.
  57. 1 2 Lerner, Martin (1984). The flame and the lotus : Indian and Southeast Asian art from the Kronos collections (Exhibition Catalogue ed.). Metropolitan Museum of Art.
  58. 1 2 Ellison, Elaine; Venters, Diana (1999). Mathematical Quilts: No Sewing Required. Key Curriculum.
  59. 1 2 Castera, Jean Marc; Peuriot, Francoise (1999). Arabesques. Decorative Art in Morocco. Art Creation Realisation. ISBN 978-2-86770-124-5.
  60. Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. pp. 103–106. ISBN 978-0-521-72876-8.
  61. Dye, Daniel S. (1974). Chinese Lattice Designs. Dover. pp. 30–39.
  62. belcastro, sarah-marie (2013). "Adventures in Mathematical Knitting". American Scientist 101 (2): 124. doi:10.1511/2013.101.124.
  63. Taimina, Daina (2009). Crocheting Adventures with Hyperbolic Planes. A K Peters. ISBN 1-56881-452-6.
  64. Snook, Barbara. Florentine Embroidery. Scribner, Second edition 1967.
  65. Williams, Elsa S. Bargello: Florentine Canvas Work. Van Nostrand Reinhold, 1967.
  66. Grünbaum, Branko; Shephard, Geoffrey C. (May 1980). "Satins and Twills: An Introduction to the Geometry of Fabrics". Mathematics Magazine 53 (3): 139–161. doi:10.2307/2690105. JSTOR 2690105.
  67. Gamwell, Lynn (2015). Mathematics and Art: A Cultural History. Princeton University Press. p. 423. ISBN 978-0-691-16528-8.
  68. Baker, Patricia L.; Smith, Hilary (2009). Iran (3 ed.). Bradt Travel Guides. p. 107. ISBN 1-84162-289-3.
  69. Irvine, Veronika; Ruskey, Frank (2014). "Developing a Mathematical Model for Bobbin Lace" (PDF). Journal of Mathematics and the Arts 8 (3–4): 95–110. doi:10.1080/17513472.2014.982938.
  70. Peter J. Lu and Paul J. Steinhardt (2007). "Decagonal and Quasi-crystalline Tilings in Medieval Islamic Architecture". Science 315 (5815): 1106–1110. Bibcode:2007Sci...315.1106L. doi:10.1126/science.1135491. PMID 17322056.
  71. van den Hoeven, Saskia, van der Veen, Maartje. "Muqarnas-Mathematics in Islamic Arts" (PDF). Archived from the original (PDF) on 27 September 2013. Retrieved 15 January 2016.
  72. Panofsky, E. (1955). The Life and Art of Albrecht Durer. Princeton.
  73. Hart, George W. "Dürer's Polyhedra". Retrieved 13 August 2009.
  74. Dürer, Albrecht (1528). Hierinn sind begriffen vier Bucher von menschlicher Proportion. Nurenberg: Archive.org. Retrieved 24 June 2015.
  75. Schreiber, P. (1999). "A New Hypothesis on Durer's Enigmatic Polyhedron in His Copper Engraving 'Melencolia I'". Historia Mathematica 26: 369–377. doi:10.1006/hmat.1999.2245.
  76. Dodgson, Campbell (1926). Albrecht Dürer. London: Medici Society. p. 94.
  77. Schuster, Peter-Klaus (1991). Melencolia I: Dürers Denkbild. Berlin: Gebr. Mann Verlag. pp. 17–83.
  78. Panofsky, Erwin; Klibansky, Raymond; Saxl, Fritz (1964). Saturn and melancholy. Basic Books.
  79. 1 2 "Crucifixion (Corpus Hypercubus)". Metropolitan Museum of Art. Retrieved 5 September 2015.
  80. Galilei, Galileo (1623). The Assayer., as translated in Drake, Stillman (1957). Discoveries and Opinions of Galileo. Doubleday. pp. 237–238. ISBN 0-385-09239-3.
  81. Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. p. 381. ISBN 978-0-521-72876-8.
  82. Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. p. 10. ISBN 978-0-521-72876-8.
  83. King, Jerry P. (1992). The Art of Mathematics. Fawcett Columbine. pp. 8–9. ISBN 0-449-90835-6.
  84. King, Jerry P. (1992). The Art of Mathematics. Fawcett Columbine. pp. 135–139. ISBN 0-449-90835-6.
  85. Devlin, Keith (2000). "Do Mathematicians Have Different Brains?". The Math Gene: How Mathematical Thinking Evolved And Why Numbers Are Like Gossip. Basic Books. p. 140. ISBN 978-0-465-01619-8.
  86. Wasilewska, Katarzyna (2012). "Mathematics in the World of Dance" (PDF). Bridges. Retrieved 1 September 2015.
  87. 1 2 Malkevitch, Joseph. "Mathematics and Art". American Mathematical Society. Retrieved 1 September 2015.
  88. Malkevitch, Joseph. "Mathematics and Art. 2. Mathematical tools for artists". American Mathematical Society. Retrieved 1 September 2015.
  89. "Math and Art: The Good, the Bad, and the Pretty". Mathematical Association of America. Retrieved 2 September 2015.
  90. Cohen, Louise (1 July 2014). "How to spin the colour wheel, by Turner, Malevich and more". Tate Gallery. Retrieved 4 September 2015.
  91. Kemp, Martin (1992). The Science of Art: Optical Themes in Western Art from Brunelleschi to Seurat. Yale University Press. ISBN 978-968-867-185-6.
  92. Gage, John (1999). Color and Culture: Practice and Meaning from Antiquity to Abstraction. University of California Press. p. 207. ISBN 978-0-520-22225-0.
  93. Malkevitch, Joseph. "Mathematics and Art. 3. Symmetry". American Mathematical Society. Retrieved 1 September 2015.
  94. Malkevitch, Joseph. "Mathematics and Art. 4. Mathematical artists and artist mathematicians". American Mathematical Society. Retrieved 1 September 2015.
  95. Wright, Richard (1988). "Some Issues in the Development of Computer Art as a Mathematical Art Form". Leonardo 1 (Electronic Art, supplemental issue): 103–110. doi:10.2307/1557919. JSTOR 1557919.
  96. Kalajdzievski, Sasho (2008). Math and Art: An Introduction to Visual Mathematics. Chapman and Hall. ISBN 978-1-58488-913-7.
  97. 1 2 Beddard, Honor. "Computer art at the V&A". Victoria and Albert Museum. Retrieved 22 September 2015.
  98. "Computer Does Drawings: Thousands of lines in each". The Guardian. 17 September 1962. in Beddard, 2015.
  99. O'Hanrahan, Elaine (2005). Drawing Machines: The machine produced drawings of Dr. D. P. Henry in relation to conceptual and technological developments in machine-generated art (UK 1960–1968). Unpublished MPhil. Thesis. John Moores University, Liverpool. in Beddard, 2015.
  100. Bellos, Alex (24 February 2015). "Catch of the day: mathematician nets weird, complex fish". The Guardian. Retrieved 25 September 2015.
  101. Levin, Golan (2013). "Generative Artists". CMUEMS. Retrieved 27 October 2015. This includes a link to Hvidtfeldts Syntopia.
  102. Verostko, Roman. "The Algorists". Retrieved 27 October 2015.
  103. Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. pp. 315–317. ISBN 978-0-521-72876-8.
  104. Miller, Arthur I. (2012). Insights of Genius: Imagery and Creativity in Science and Art. Springer. ISBN 1-4612-2388-1.
  105. Henderson, Linda D. (1983). The Fourth Dimension and Non-Euclidean geometry in Modern Art. Princeton University Press.
  106. Antliff, Mark; Leighten, Patricia Dee (2001). Cubism and Culture (PDF). Thames & Hudson.
  107. Everdell, William R. (1997). The First Moderns: Profiles in the Origins of Twentieth-Century Thought. University of Chicago Press. p. 312. ISBN 0-226-22480-5.
  108. Green, Christopher (1987). Cubism and its Enemies, Modern Movements and Reaction in French Art, 1916–1928. Yale University Press. pp. 13–47.
  109. Metzinger, Jean (October–November 1910). "Note sur la peinture". Pan: 60. in Miller. Einstein, Picasso. Basic Books. p. 167.
  110. Metzinger, Jean (1972). Le cubisme était né. Éditions Présence. pp. 43–44. in Ferry, Luc (1993). Homo Aestheticus: The Invention of Taste in the Democratic Age. Robert De Loaiza, trans. University of Chicago Press. p. 215. ISBN 0-226-24459-8.
  111. "Man Ray–Human Equations A Journey from Mathematics to Shakespeare. February 7 – May 10, 2015". Phillips Collection. Retrieved 5 September 2015.
  112. Adcock, Craig (1987). "Duchamp's Eroticism: A Mathematical Analysis". Iowa Research Online 16 (1): 149–167.
  113. Elder, R. Bruce (2013). DADA, Surrealism, and the Cinematic Effect. Wilfrid Laurier University Press. p. 602. ISBN 978-1-55458-641-7.
  114. Tubbs, Robert (2014). Mathematics in Twentieth-Century Literature and Art: Content, Form, Meaning. JHU Press. p. 118. ISBN 978-1-4214-1402-7.
  115. "Hiroshi Sugimoto Conceptual Forms and Mathematical Models February 7 – May 10, 2015". Phillips Collection. Retrieved 5 September 2015.
  116. Tubbs, Robert (2014). Mathematics in 20th-Century Literature and Art. Johns Hopkins. pp. 8–10. ISBN 978-1-4214-1380-8.
  117. Keats, Jonathon (13 February 2015). "See How Man Ray Made Elliptic Paraboloids Erotic At This Phillips Collection Photography Exhibit". Forbes. Retrieved 10 September 2015.
  118. Gamwell, Lynn (2015). Mathematics and Art: A Cultural History. Princeton University Press. pp. 311–312. ISBN 978-0-691-16528-8.
  119. Hedgecoe, John, ed. (1968). Henry Moore: Text on His Sculpture. Henry Spencer Moore (Simon and Schuster). p. 105.
  120. 1 2 "De Stijl". Tate Glossary. The Tate. Retrieved 11 September 2015.
  121. Curl, James Stevens (2006). A Dictionary of Architecture and Landscape Architecture (Second ed.). Oxford University Press. ISBN 0-19-860678-8.
  122. Tubbs, Robert (2014). Mathematics in Twentieth-Century Literature and Art: Content, Form, Meaning. JHU Press. pp. 44–47. ISBN 978-1-4214-1402-7.
  123. "Tour: M.C. Escher – Life and Work". NGA. Retrieved 13 August 2009.
  124. "MC Escher". Mathacademy.com. 1 November 2007. Retrieved 13 August 2009.
  125. Penrose, L.S.; Penrose, R. (1958). "Impossible objects: A special type of visual illusion". British Journal of Psychology 49: 31–33. doi:10.1111/j.2044-8295.1958.tb00634.x. PMID 13536303.
  126. Kirousis, Lefteris M.; Papadimitriou, Christos H. (1985). "The complexity of recognizing polyhedral scenes". 26th Annual Symposium on Foundations of Computer Science (FOCS 1985): 175–185. doi:10.1109/sfcs.1985.59.
  127. Cooper, Martin (2008). "Tractability of Drawing Interpretation". Line Drawing Interpretation. Springer-Verlag. pp. 217–230. doi:10.1007/978-1-84800-229-6_9. ISBN 978-1-84800-229-6.
  128. Roberts, Siobhan (2006). 'Coxetering' with M.C. Escher. King of Infinite Space: Donald Coxeter, the Man Who Saved Geometry (Walker). p. Chapter 11.
  129. Escher, M.C. (1988). The World of MC Escher. Random House.
  130. Escher, M.C.; Vermeulen, M.W.; Ford, K. (1989). Escher on Escher: Exploring the Infinite. HN Abrams.
  131. Malkevitch, Joseph. "Mathematics and Art. 5. Polyhedra, tilings, and dissections". American Mathematical Society. Retrieved 1 September 2015.
  132. "John Robinson". Bradshaw Foundation. 2007. Retrieved 13 August 2009.
  133. "Helaman Ferguson web site". Helasculpt.com. Retrieved 13 August 2009.
  134. Thurston, William P. (1999). Levy, Silvio, ed. The Eightfold Way: A Mathematical Sculpture by Helaman Ferguson (PDF). Volume 35: The Eightfold Way: The Beauty of Klein's Quartic Curve (MSRI Publications). pp. 1–7.
  135. "MAA book review of ''The Eightfold Way: The Beauty of Klein's Quartic Curve''". Maa.org. 14 November 1993. Retrieved 13 August 2009.
  136. "The Math Geek Holiday Gift Guide". Scientific American. 23 November 2014. Retrieved 7 June 2015.
  137. Hanna, Raven. "Gallery: Bathsheba Grossman". Symmetry Magazine. Retrieved 7 June 2015.
  138. Fleron, Julian F.; Ecke, Volker; von Renesse, Christine; Hotchkiss, Philip K. (January 2015). Art and Sculpture: Mathematical Inquiry in the Liberal Arts (2nd ed.). Discovering the Art of Mathematics project.
  139. Osinga, Hinke (2005). "Crocheting the Lorenz manifold". University of Auckland. Archived from the original on 10 April 2015. Retrieved 12 October 2015.
  140. Henderson, David; Taimina, Daina (2001). "Crocheting the hyperbolic plane" (PDF). Mathematical Intelligencer 23 (2): 17–28. doi:10.1007/BF03026623..
  141. Osinga, Hinke M; Krauskopf, Bernd (2004). "Crocheting the Lorenz manifold". The Mathematical Intelligencer 26 (4): 25–37. doi:10.1007/BF02985416.
  142. Dietz, Ada K. (1949), Algebraic Expressions in Handwoven Textiles (PDF), Louisville, Kentucky: The Little Loomhouse
  143. Miller, J. C. P. (1970). "Periodic forests of stunted trees". Philosophical Transactions of the Royal Society of London. Series A, Mathematical and Physical Sciences 266 (1172): 63–111. doi:10.1098/rsta.1970.0003. JSTOR 73779.
  144. "Pat Ashforth & Steve Plummer – Mathekniticians". Woolly Thoughts. Retrieved 4 October 2015.
  145. Ward, Mark (20 August 2012). "Knitting reinvented: Mathematics, feminism and metal". BBC. Retrieved 23 September 2015.
  146. Ashforth, Pat; Plummer, Steve. "Menger Sponge". Woolly Thoughts: In Pursuit of Crafty Mathematics. Retrieved 23 September 2015.
  147. Ashforth, Pat; Plummer, Steve. "Afghans for Schools". Woolly Thoughts: Mathghans. Retrieved 23 September 2015.
  148. "Mathghans with a Difference". Simply Knitting Magazine. 1 July 2008. Retrieved 23 September 2015.
  149. "Giotto di Bondone and assistants: Stefaneschi triptych". The Vatican. Retrieved 16 September 2015.
  150. Gamwell, Lynn (2015). Mathematics and Art: A Cultural History. Princeton University Press. pp. 337–338. ISBN 978-0-691-16528-8.
  151. Cooper, Jonathan (5 September 2007). "Art and Mathematics". Retrieved 5 September 2015.
  152. Hofstadter, Douglas R. (1980). Gödel, Escher, Bach: An Eternal Golden Braid. Penguin. p. 627. ISBN 978-0-14-028920-6.
  153. Hall, James (10 June 2011). "René Magritte: The Pleasure Principle – exhibition". The Guardian. Retrieved 5 September 2015.
  154. King, Elliott (2004). Ades, Dawn, ed. Dali. Milan: Bompiani Arte. pp. 418–421.
  155. Hofstadter, Douglas R. (1980). Gödel, Escher, Bach: An Eternal Golden Braid. Penguin. pp. 98–99, 690–717. ISBN 978-0-394-74502-2.
  156. de Smit, B. (2003). "The Mathematical Structure of Escher's Print Gallery". Notices of the American Mathematical Society 50 (4): 446–451.
  157. Lenstra, Hendrik; De Smit, Bart. "Applying mathematics to Escher's Print Gallery". Leiden University. Retrieved 10 November 2015.
  158. Stanek, Becca (16 June 2014). "Van Gogh and the Algorithm: How Math Can Save Art". Time Magazine. Retrieved 4 September 2015.
  159. Sipics, Michelle (18 May 2009). "The Van Gogh Project: Art Meets Mathematics in Ongoing International Study". Society for Industrial and Applied Mathematics. Retrieved 4 September 2015.
  160. Emmerling, Leonhard (2003). Jackson Pollock, 1912–1956. p. 63. ISBN 3-8228-2132-2.
  161. Taylor, Richard P.; Micolich, Adam P.; Jonas, David (June 1999). "Fractal analysis of Pollock's drip paintings" (PDF). Nature 399: 422.
  162. Taylor, Richard; Micolich, Adam P.; Jonas, David (October 1999). "Fractal Expressionism: Can Science Be Used To Further Our Understanding Of Art?". Physics World 12: 25–28. doi:10.1088/2058-7058/12/10/21. Pollock died in 1956, before chaos and fractals were discovered. It is highly unlikely, therefore, that Pollock consciously understood the fractals he was painting. Nevertheless, his introduction of fractals was deliberate. For example, the colour of the anchor layer was chosen to produce the sharpest contrast against the canvas background and this layer also occupies more canvas space than the other layers, suggesting that Pollock wanted this highly fractal anchor layer to visually dominate the painting. Furthermore, after the paintings were completed, he would dock the canvas to remove regions near the canvas edge where the pattern density was less uniform.
  163. King, M. (2002). "From Max Ernst to Ernst Mach: epistemology in art and science." (PDF). Retrieved 17 September 2015.
  164. Dodgson, N. A. (2012). "Mathematical characterisation of Bridget Riley's stripe paintings" (PDF). Journal of Mathematics and the Arts 5: 1–21. doi:10.1080/17513472.2012.679468. over the course [of] the early 1980s, Riley's patterns moved from more regular to more random (as characterised by global entropy), without losing their rhythmic structure (as characterised by local entropy). This reflects Kudielka's description of her artistic development.
  165. Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. pp. 116–120. ISBN 978-0-521-72876-8.
  166. Treibergs, Andrejs (24 July 2001). "The Geometry of Perspective Drawing on the Computer". University of Utah. Retrieved 5 September 2015.
  167. Gamwell, Lynn (2015). Mathematics and Art: A Cultural History. Princeton University Press. p. xviii. ISBN 978-0-691-16528-8.
  168. Malkevitch, Joseph. "Mathematics and Art. 6. Origami". American Mathematical Society. Retrieved 1 September 2015.
  169. T. Sundara Rao (1893). Geometric Exercises in Paper Folding. Addison.
  170. Justin, J. (June 1986). "Mathematics of Origami, part 9". British Origami: 28–30..
  171. Alsina, Claudi; Nelsen, Roger (2010). Charming Proofs: A Journey Into Elegant Mathematics. Dolciani Mathematical Expositions 42. Mathematical Association of America. p. 57. ISBN 978-0-88385-348-1.
  172. Alperin, Roger C.; Lang, Robert J. (2009). "One-, Two-, and Multi-Fold Origami Axioms" (PDF). 4OSME (A K Peters).
  173. Cucker, Felix (2013). Manifold Mirrors: The Crossing Paths of the Arts and Mathematics. Cambridge University Press. pp. 163–166. ISBN 978-0-521-72876-8.
  174. Gamwell, Lynn (2015). Mathematics and Art: A Cultural History. Princeton University Press. pp. 406–410. ISBN 978-0-691-16528-8.
  175. Ghyka, Matila (2003). The Geometry of Art and Life. Dover. pp. ix–xi. ISBN 978-0-486-23542-4.
  176. Lawlor, Robert (1982). Sacred Geometry: Philosophy and Practice. Thames & Hudson. ISBN 978-0-500-81030-9.
  177. 1 2 Calter, Paul (1998). "Celestial Themes in Art & Architecture". Dartmouth College. Retrieved 5 September 2015.
  178. "The Thought of a Thought – Edgar Allan Poe". MathPages. Retrieved 5 September 2015.
  179. Livio, Mario. "The golden ratio and aesthetics". Retrieved 26 June 2015.

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