Math of the world.If you know where to look, you can find math anywhere you go. Math is not just in the numbers on a cash register or at a football game. It's in bathroom- tiling patterns, the shapes of clouds and trees, the arrangement of a flower's petals, a ball's path in a pinball game, the knots you tie in your shoelaces--and even in the way you lace your shoes (see "How to Lace Like an Ace"). Ron Eglash has gone even farther. He's found math in beadwork beadwork Ornamental work in beads. In the Middle Ages beads were used to embellish embroidery work. In Renaissance and Elizabethan England, clothing, purses, fancy boxes, and small pictures were adorned with beads. , basket weaving Basket weaving (or basket making, basketry, or basketmaking) is the process of weaving unspun vegetable fibers into a basket. People with the profession of weaving baskets are basketmakers. , Navajo rugs, modern music, and even cornrow corn·row tr.v. corn·rowed, corn·row·ing, corn·rows To arrange or style (hair) by dividing into sections and braiding close to the scalp in rows. hairstyles. Eglash is a professor at Rensselaer Polytechnic Institute Rensselaer Polytechnic Institute, at Troy, N.Y.; coeducational; founded and opened 1824 as Rensselaer School; chartered 1826. It was called Rensselaer Institute from 1837 to 1861. in Troy, N.Y. The best way to get students excited about math, Eglash says, is to apply it to things that they care about. With this goal in mind, he has created computer programs that reveal mathematical principles in everything from graffiti art and the architecture of African villages to Native American beadwork and Puerto Rican Puer·to Ri·co Abbr. PR or P.R. A self-governing island commonwealth of the United States in the Caribbean Sea east of Hispaniola. music. As students create and experiment, they learn math in a way that makes sense to them. "Kids already know the mathematics, but they know it in a form that isn't recognized in school," Eglash says. "We're getting kids to take something they already know in their hearts and hands and to use computers to translate that into the kind of math their schools understand." Fractal factor Eglash first noticed the link between culture and math when he saw photographs of Africa taken from airplanes. Huts in many villages, he noted, are built in circles of circles of circles, or in rectangles of rectangles of rectangles. In math, a pattern that repeats itself on different scales is called a fractal. In a fractal object, each smaller structure is a miniature copy of the larger form. Fractals often appear in nature. A tree, for instance, has branches that split into branches that split into more branches, and so on. The rules that underlie fractals are simple. But the resulting patterns can be complex (see "Creating a Fractal Snowflake," below). The people who live in fractal-based villages in Africa use math to reflect spiritual concepts, Eglash says. They believe that life is a never-ending cycle and that our ancestors Our Ancestors (Italian: I Nostri Antenati) is the name of Italo Calvino's "heraldic trilogy" that comprises The Cloven Viscount (1952), The Baron in the Trees (1957), and The Nonexistent Knight (1959). are always with us. Repeating patterns can also represent the desire for unending health or wealth. Eglash found fractals not only in village design but also in African sculptures, textiles, and other art forms. Four points Math and culture work together in other places, Eglash says. Many Native American groups, for instance, find meaning in four points that mirror each other, whether there be four directions, winds, colors, or mountains. Such four-point symmetry appears in these people's beadwork, tepee tepee or tipi (both: tē`pē), typical dwelling of Native North Americans living on the Great Plains. It was usually made by arranging tent poles into a conical frame and spreading skins, usually buffalo hide, tightly over construction, buffalo-hide drum decorations, sand paintings, and more. In the eyes of a mathematician, these patterns belong to something called the Cartesian coordinate Cartesian coordinate n. A member of the set of numbers that locates a point in a Cartesian coordinate system. Noun 1. Cartesian coordinate system. The images fit onto graphs with an x-axis and a y-axis, where each point on the graph is given by two numbers, or coordinates. And there are sets of rules, called algorithms, that tell you how draw these shapes step by step on graph paper (or a computer screen). Using Eglash's Virtual Bead Loom program, you can experiment with the Cartesian coordinate system to make your own beautiful works of art. You can also try the Graffiti Grapher, Navajo Rug Weaver, and Alaskan Basket Weaver, all based on the same concept. Drumbeats and cornrows Cornrows are a traditional style of hair grooming of African origin where the hair is tightly braided very close to the scalp, using an underhand, upward motion to produce a continuous, raised row. Among Eglash's other creations is a program called Rhythm Wheels. It challenges kids to figure out when two repeating sets of drumbeats, each going at its own pace, will meet. As they work with this program, kids learn about fractions and finding the least common denominator least common denominator n. Abbr. lcd The least common multiple of the denominators of a set of fractions: The least common denominator of 1/3 and 1/4 is 12. . Cornrow Curves, another program, teaches transformational geometry. Students work with repeating patterns and changes in scale to create new hairstyles. Eglash can't look anywhere without seeing a math lesson just waiting to be taught. His newest program, still under construction, uses a break-dancing robot to explain angles involved in three-dimensional movement around an axis. Eglash's math programs are popular with students. According to according to prep. 1. As stated or indicated by; on the authority of: according to historians. 2. In keeping with: according to instructions. 3. recent studies, a group of mostly minority kids felt better about computers after using them. And a group of mostly Latin American students improved their math grades after using the tools. Math appreciation In Native American communities, elders appreciate the lessons, too, because kids learn about the history of their people. In fact, each of Eglash's programs includes information about the culture, history, and math involved. Once parents and grandparents grandparents npl → abuelos mpl grandparents grand npl → grands-parents mpl grandparents grand npl consider schoolwork to be culturally valuable, they become more likely to encourage their kids to study, says Jim Barta. He's a professor at Utah State University Utah State University, mainly at Logan; coeducational; land-grant and state supported; chartered 1888, opened 1890. It publishes Utah Science, Western Historical Quarterly, and Western American Literary Journal. in Logan. "Parents say, 'Wow, I wish I'd had teachers that taught me math that way. I might have liked it!'" Barta says. Ultimately, mixing math with culture could do more than help kids learn. It could also help them understand each other better. "Culture is usually a barrier to math," Eglash says. "We are using math as a bridge to culture." Creating a Fractal Snowflake You will need: * pencil * ruler * sheet of paper * protractor protractor Instrument for constructing and measuring plane angles. The simplest protractor is a semicircular disk marked in degrees from 0° to 180°. A more complex protractor, for plotting position on navigation charts, is called a three-arm protractor, or station for measuring angles to draw triangles What to do: 1. Draw an equilateral triangle equilateral triangle perfect geometrical representation of triune God. [Christian Symbolism: Appleton, 102] See : Trinity with each side measuring 9 centimeters (above left). (Remember, each angle of an equilateral triangle measures 60[degrees]. [ILLUSTRATION OMITTED] 2. Divide each 9-centimeter side into three equal parts, each measuring 3 centimeters. At the middle of each side, add an equilateral triangle one-third the size of the original, facing outward. Because each side of the original triangle 9 centimeters, the new, smaller triangles will have 3-centimeter sides. When you examine the outer edge of your diagram, you should see a six-pointed star made up of 12 line segments (above middle). [ILLUSTRATION OMITTED] 3. At the middle of each segment of the star, add a triangle one-ninth the size of the original triangle. The new triangle will have sides 1 centimeter in length, so divide each 3-centimeter segment into thirds, and use the middle third to form a new triangle (above right). [ILLUSTRATION OMITTED] 4. Going one set further, you create a shape that begins to resemble a snowflake (below). [ILLUSTRATION OMITTED] If you were to continue the process by endlessly adding smaller and smaller triangles to every new side, you would produce a fractal object that mathematicians call the von Koch snowflake curve, named after a Swedish mathematician, Niels Fabian Helge von Koch Niels Fabian Helge von Koch (January 25, 1870 - March 11, 1924) was a Swedish mathematician, who gave his name to the famous fractal known as the Koch snowflake, which was one of the earliest fractal curves to have been described. . |
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