Crafty geometry: mathematicians are knitting and crocheting to visualize complex surfaces.During the 2002 winter holidays, mathematician Hinke Osinga was relaxing with some lace crochet work crochet work (krōshā`), form of knitting done with a hook, by means of which loops of thread or yarn are drawn through other, preceding loops. Crochet stitches are all based on the chain or single crochet, i.e., a single loop. when her partner and mathematical collaborator Bernd Krauskopfasked, "Why don't you crochet something useful?" Some crocheters might bridle at Verb 1. bridle at - show anger or indignation; "She bristled at his insolent remarks" bridle up, bristle at, bristle up mind - be offended or bothered by; take offense with, be bothered by; "I don't mind your behavior" the suggestion that lace is useless, but for Osinga, Krauskopf's question sparked an exciting idea. "I looked at him, and we thought the same thing at the same moment," Osinga recalls. "We realized that you could crochet the Lorenz manifold." For years, Osinga and Krauskopf, both of the University of Bristol in England, had been studying the Lorenz manifold, a complicated surface that emerges from a model of chaotic weather systems. The pair had created an algorithm to generate 2-dimensional computer visualizations of the surface, but Osinga found the flat images unsatisfying. When Kranskopfasked his question, she suddenly realized that the computer algorithm could be interpreted as crochet instructions. "I had to try it" she says. Eighty-five hours and 25,511 crochet stitches later, Osinga had a Lorenz manifold almost a meter tall and about 25 centimeters in diameter, which now hangs in the pair's house as a decoration. Mathematics has long been an essential tool for the fiber arts. Knitters and crocheters use mathematical principles--often without recognizing them as such--to map the pattern of a cable sweater, for instance, or figure out how to space the stitches when adding a sleeve onto a jacket. Now, the two crafts are returning the favor. In recent years, mathematicians such as Osinga have started knitting and crocheting concrete physical models of hard-to-visualize mathematical objects. One mathematician's crocheted models of a counter-intuitive shape called a hyperbolic hy·per·bol·ic also hy·per·bol·i·cal adj. 1. Of, relating to, or employing hyperbole. 2. Mathematics a. Of, relating to, or having the form of a hyperbola. b. plane are enabling her students and fellow mathematicians to gain new insight into startling star·tle v. star·tled, star·tling, star·tles v.tr. 1. To cause to make a quick involuntary movement or start. 2. To alarm, frighten, or surprise suddenly. See Synonyms at frighten. properties. Other mathematicians have knitted or crocheted fractal objects, surfaces that have no inside or outside, and shapes whose patterns display mathematical theorems. "Knitting and crocheting are helping us think about math we already know in a different light,' says Carolyn Yackel, a mathematician at Mercer University Mercer University is a private, coeducational, faith-based university with a Baptist heritage, located in the U.S. state of Georgia. Mercer is the only university of its size in the United States that offers programs in eleven diversified fields of study: liberal arts, in Macon, Ga. A HYPERBOLIC YARN In 1997, as Daina Taimina Daina Taimina is a Latvian mathematician at Cornell University who crochets objects to illustrate hyperbolic space. She came up with the idea in an idle moment during a camping trip in 1997, based on paper models designed by geometer William Thurston. geared up to teach an undergraduate-geometry class, she faced a challenge. As a visiting mathematician at Cornell University Cornell University, mainly at Ithaca, N.Y.; with land-grant, state, and private support; coeducational; chartered 1865, opened 1868. It was named for Ezra Cornell, who donated $500,000 and a tract of land. With the help of state senator Andrew D. , she planned to cover the basic geometries of three types of surfaces: planar A technique developed by Fairchild Instruments that creates transistor sublayers by forcing chemicals under pressure into exposed areas. Planar superseded the mesa process and was a major step toward creating the chip. , or Euclidean; spherical; and hyperbolic. She knew that everyone can use intuition to conceive of Verb 1. conceive of - form a mental image of something that is not present or that is not the case; "Can you conceive of him as the president?" envisage, ideate, imagine the first two geometries, which are the realms of, say, sheets of paper and basketballs. The hyperbolic plane, however, lies outside of daily experience of the physical world. Geometry teachers usually try to explain the hyperbolic plane via flat models that wildly distort its geometry--making lines look like semicircles, for instance. How, Taimina wondered, could she give her students a feel for hyperbolic geometry's counter-intuitive properties? While attending a workshop, the answer came to her: Crochet a piece of hyperbolic fabric. In a flat plane or a sphere, the circumference of a circle grows at most linearly as the radius increases. By contrast, in the hyperbolic plane, the circumference of a circle grows exponentially. As a result, the hyperbolic plane is somewhat like a carpet that, too big for its room, buckles and flares out more and more as it grows. In 1901, mathematician David Hilbert Noun 1. David Hilbert - German mathematician (1862-1943) Hilbert proved that because of this buckling, it's impossible to build a smooth model of the hyperbolic plane. His result, however, left the door open for models that are not perfectly smooth. In the 1970s, William Thurstou, now also at Cornell, described a way to build an approximate physical model of the hyperbolic plane by taping together paper arcs into rings whose circumferences grow exponentially. However, these models take many hours to build and are so fragile that they generally need to be protected from much rough-and-tumble hands-on study. Taimina realized that she could crochet a durable model of the hyperbolic plane using a simple rule: Increase the number of stitches in each row by a fixed factor, by adding a new stitch after, for instance, every two (or three or four or n) stitches. In 2001, Taimina and her Cornell colleague David Henderson David Henderson may be:
Taimina's models have made it easy to study hyperbolic lines--the shortest paths between two points on the hyperbolic plane. Given two points, all that's necessary is to grab each point and gently pull tight the fabric between them. The line can then be marked, for future reference, by sewing yarn along it. Taimina has used these sewn lines in the classroom to illustrate the hyperbolic plane's most famous property. The plane violates Euclid's parallel postulate parallel postulate One of the five postulates, or axioms, of Euclid underpinning Euclidean geometry. It states that through any given point not on a line there passes exactly one line parallel to that line in the same plane. , which states that given a line and a point off the line, there is just one line through the point that never meets the given line. By sewing lines with yarn, Taimina's students have observed that in the hyperbolic plane there are, in fact, infinitely many lines through a given point that never meet a given line. Loosely speaking, this happens because the hyperbolic plane's extreme flaring makes certain lines veer away from each other instead of intersecting as they would in a flat plane. Because the hyperbolic plane is so hard to visualize, Taimina's crocheted models are helping even seasoned mathematicians develop a better intuition for its properties. Taimina recalls that one mathematician, upon examining one of her hyperbolic planes, exclaimed, "So that's what they look like!" Taimina has crocheted models for many mathematics departments and for the Smithsonian Institution Smithsonian Institution, research and education center, at Washington, D.C.; founded 1846 under terms of the will of James Smithson of London, who in 1829 bequeathed his fortune to the United States to create an establishment for the "increase and diffusion of as examples of math teaching tools, but she now thinks twice before agreeing to make someone a model. Because of the exponential growth Extremely fast growth. On a chart, the line curves up rather than being straight. Contrast with linear. , crocheting a hyperbolic plane takes a long time. For instance, one of Talmina's models started with a 1.5-inch row, but the 20th row was already more than 30 feet long. What's more, the crochet work is hard on the hands, Taimina says, since the stitches must be tight to prevent the fabric from stretching out of its characteristic hyperbolic shape. Luckily for Taimina, many mathematicians "are now enthusiastically making their own models," she says. Taimina's hyperbolic planes have also attracted interest from art lovers. Her models have appeared in art shows all over the United States United States, officially United States of America, republic (2005 est. pop. 295,734,000), 3,539,227 sq mi (9,166,598 sq km), North America. The United States is the world's third largest country in population and the fourth largest country in area. , and some are currently on display in Latvia and Italy. "I have met so many people now who don't have a math background, but who want to understand what these hyperbolic planes mean," Taimina says. "It makes me happy that people can learn beautiful geometry and not be intimidated." CROCHETED CHAOS Osinga launched her crochet project in the hopes of finally getting her hands on a Lorenz manifold, a mathematical object that she had been studying theoretically for years. Meteorologist Edward Lorenz (person) Edward Lorenz - A mathematical meteorologist who discovered the Lorenz attractor in the 1960s. , now an emeritus professor at the Massachusetts Institute of Technology Massachusetts Institute of Technology, at Cambridge; coeducational; chartered 1861, opened 1865 in Boston, moved 1916. It has long been recognized as an outstanding technological institute and its Sloan School of Management has notable programs in business, , had set down three equations in 1963 as a highly simplified description of weather dynamics. These Lorenz equations have tremendous mathematical and historical significance. While simulating the equations' dynamics on a computer, Lorenz found that tiny round-off errors result in hugely different outcomes, a discovery that launched the field of chaos theory chaos theory, in mathematics, physics, and other fields, a set of ideas that attempts to reveal structure in aperiodic, unpredictable dynamic systems such as cloud formation or the fluctuation of biological populations. . Osinga explains that Lorenz' equations describe a flow in three-dimensional space Three-dimensional space is the physical universe we live in. The three dimensions are commonly called length, width, and breadth, although any three mutually perpendicular directions can serve as the three dimensions. Pictures are commonly two dimensional, they lack depth. , and the Lorenz manifold corresponds to a certain specific part of a river. "If you throw a leaf in the water and watch it flow downstream toward a rock, the leaf might go to the right or left of the rock," she says. "But there are particular points where, if you drop the leaf exactly there, it will flow down and get stuck on the rock." The Lorenz manifold is the two-dimensional surface consisting of all the points where you can drop a leaf and it will flow to the rock, which is represented by the central point, or origin, in a three-dimensional coordinate space In mathematics, specifically in linear algebra, the coordinate space, Fn, is the prototypical example of an n-dimensional vector space over a field F. It can be defined as the product space of F over a finite index set. . Since the system is chaotic, the Lorenz manifold twists around with many changes in curvature. To build a computer image of the surface, Osinga and Krauskopf devised an algorithm that starts at the origin and works its way outward in concentric rings. For each ring, the algorithm looks for points from which an object would flow to the origin. The algorithm can't find all such points, since there are infinitely many, so instead it identifies a collection of prototypical points that are about evenly spaced along the surface and then connects neighboring points by links so that the resulting mesh will resemble the Lorenz surface. In areas where the surface has floppy, hyperbolic geometry hyperbolic geometry Non-Euclidean geometry, useful in modeling interstellar space, that rejects the parallel postulate, proposing instead that at least two lines through any point not on a given line are parallel to that line. , the algorithm will identify many mesh points; where the surface has more tightly curved geometry, the algorithm will identify fewer points. Osinga realized that the mesh instructions could be read as a erochet pattern: Crochet outward in rings and simply add or remove stitches to suit the mesh pattern. As the fabric grew under her nimble fingers--Osinga has been crocheting since age 7--it automatically took on the curvature of the Lorenz manitbld. "Just local information about where to increase stitches created the entire global shape," Osinga says. When Osinga had finished crocheting, she and Kranskopf mounted the fabric on garden wire, and it indeed took the shape of the Lorenz manifold, Osinga says. Unlike Taimina's hyperbolic planes, whose crochet instructions can be summed up in a single sentence, the instructions for the Lorenz surface fill two pages of a paper that Osinga and Kranskopf published in 2004. "An expert needleworker Noun 1. needleworker - someone who does work (as sewing or embroidery) with a needle edger - a person who puts finishing edges on a garment embroiderer - someone who ornaments with needlework will be able to [crochet a hyperbolic plane] while having a nice conversation or watching TV," the pair say in the paper. "Crocheting the Lorenz manifold, on the other hand, requires continuous attention to the instructions in order not to miss when to add or indeed remove an extra crochet stitch." Despite the difficulty of making a Lorenz manifold, Osinga hears regularly from crocheters trying to follow her pattern, which is available at a link from her Web site. "I get emails from crafters who are not at all scientifically inclined but want to understand what they are making," she says. "They ask very intelligent math questions." Like Taimina's hyperbolic planes, Osinga's Lorenz manifold has taken to the road frequently since its construction, making appearances at mathematical conferences, at art shows, and even on television news. "In my teaching, the students take me way more seriously now," she says. "This complicated math I do, which seems so useless, gets you on TV." A MENAGERIE OF MODELS While Taimina's and Osinga's models have achieved the most fame, a host of other mathematicians in recent years has started crocheting and knitting mathematical shapes Following is a list of some mathematically well-defined shapes. See also list of polygons, polyhedra and polytopes and list of geometric shapes. 0D with no surface
It's not clear just why mathematical craftwork craft·work n. Work made or done by craftspeople. craft  work er n. has suddenly taken off, says sarah-marie belcastro, a mathematician at Smith College in Northampton (Mass.), who organized the exhibit with Yackel. "Part of me says it's because there are so many more women in math now," she says. "But every time we give talks, there are men in the audience who say they knit or crochet." For a gathering last March in Atlanta to honor mathematics writer Martin Gardner Martin Gardner (b. October 21, 1914, Tulsa, Oklahoma) is a popular American mathematics and science writer specializing in recreational mathematics, but with interests encompassing magic (conjuring), pseudoscience, literature (especially Lewis Carroll), philosophy, and religion. , belcastro and Yackel created doughnut-shaped surfaces, called tori. The patterns on their tori illustrate two well-known mathematical ideas about maps and networks on a torus torus /to·rus/ (tor´us) pl. to´ri [L.] a swelling or bulging projection. to·rus n. pl. . Given a map showing several countries, consider the ways to color each country so that no neighboring countries have the same color. In 1976, mathematicians famously proved that in the flat plane, no such map would require more than four colors. On a torus, however, where there are more ways for a country to wrap around and touch another country, mathematicians showed as long ago as 1890 that as many as seven colors can be required. Yackel's crocheted torus displays one seven-color map that, remarkably, has only seven countries on it--every country touches every other. Belcastro's knitted toms, which can be seen as a companion piece to Yackel's, displays an intriguing fact about networks on the toms. The torus depicts a collection of points connected by paths. This network is derived from the map on Yackel's torus by marking one point inside each country and then connecting each pair of points by a path, like a railroad line, that crosses the boundary between their respective countries. Such a network of seven points, each connected to every other by a path, can't be drawn in the flat plane without some paths crossing. On the toms, however, as belcastro's knitting demonstrates, the paths can snake around the hole and avoid each other. Belcastro and Yackel thought that making the tori would be a simple matter since pictures of the seven-color map and the corresponding network on the torus are readily available. However, it turned out to be "a nightmare," belcastro says. The challenge was figuring out how to make lines and boundaries look smooth despite the discrete nature of the stitching. Yackel and belcastro are now editing a book to be called Making Mathematics with Needlework needlework, work done with a needle, either plain sewing, mending, or ornamental work such as embroidery, quilting, smocking, hemstitching, fagoting, some kinds of lace making (see lace), patchwork, and appliqué. . It will feature patterns and mathematical discussions of 10 craft projects, including knitting, crocheting, embroidery, and quilting quilting, form of needlework, almost always created by women, most of them anonymous, in which two layers of fabric on either side of an interlining (batting) are sewn together, usually with a pattern of back or running (quilting) stitches that hold the layers . The book isn't due out until spring. Nevertheless, this holiday season, instead of the ubiquitous gift sweater, you might want to consider knitting a Mobius scarf or a Klein bottle hat, or crocheting some hyperbolic Christmas tree Christmas tree Evergreen tree, usually decorated with lights and ornaments, to celebrate the Christmas season. The use of evergreen trees, wreaths, and garlands as symbols of eternal life was common among the ancient Egyptians, Chinese, and Hebrews. ornaments. CHAOTIC CRAFTWORK--A crocheted Lorenz manifold brings the shape's swirls into shaw relief HYPERBOLIC FABRIC--Many of the lines that could be inscribed in·scribe tr.v. in·scribed, in·scrib·ing, in·scribes 1. a. To write, print, carve, or engrave (words or letters) on or in a surface. b. To mark or engrave (a surface) with words or letters. on this crocheted hyperbolic plane curve away from each other, defying OFF THE HOOK--Line-by-line crocheting instructions that tell where to increase or decrease numbers of stitches create the global shape of the Lorenz manifold. DOUGHNUT MATH--The two tori at top display a network (left) and a colored map of countries (right) that can't be depicted on a flat sheet of paper without crossings and overlaps. HYPER GROWTH--Because the hyperbolic plane grows exponentially, the violet outer boundary consumes as much yarn as the deep-purple center section does. |
|
||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion