Teaching mathematics in informal settings is a relatively new phenomenon, but it has gained more attention due to the recent changes in the society. The aim of the present quantitative study was to compare the learning outcomes of Latvian and Swedish 12-year-olds when they visited a science centre mathematics-art exhibition originally designed in Estonia. The results showed that in general, prior knowledge of the exhibition contents was the strongest predictor of post-test results in both countries but that mathematical thinking skills and self-concept had a small added value in explaining the
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Hannu SalmiMari-Pauliina VainikainenHelena Thuneberg
Assuming that scientific development and artistic research are genetically similar, this article shows the common need of knowledge of art and science, their dialectical and multidirectional relations and the unstable boundaries between them. The fractal art has assimilated the cognitive and perceptive changes in the realm of non-euclidean geometries and has become a precise instrument of "epistemological observation". Artistic practices materialize and communicate the laws of science, while scientific revolutions are in actual facts metaphorical revolutions.
In this article, science center and museum professionals from around the world share ways that they are engaging visitors in hands-on innovation. Work from the following organizations are discussed: Exploratorium, Discovery Center of Idaho, Lawrence Hall of Science, Iridescent, Conner Prairie Interactive History Park, Ideum, Discovery Place, Ontario Science Centre, Bootheel Youth Museum, Science Centre Singapore, Children's Museum of Phoenix, Discovery Museums (Acton, MA), Discovery Center of Springfield, Missouri, Museum of Science, Boston, Questacon--The National Science and Technology
The project "Microetching of the Human Brain" endeavors to create the most comprehensive illustration of the human brain that has ever existed. Investigators will utilize reflective microetching, a process combining mathematics and optics to create an art piece that evolves based on the position of the viewer. Microetching allows the depiction of very complex brain activity at incredibly fine detail. The final piece will be a wall-sized piece of fine art experienced by a diverse population of thousands daily at the Franklin Institute in Philadelphia. Additionally, this project is an educational opportunity for undergraduate students through direct involvement in the creation of the piece. As this project spans many scientific and artistic disciplines, students will be given an opportunity to learn about fields apart from their own, to broaden their skill set, and to learn how to communicate scientific concepts effectively. This project is a collaboration between neuroscientists, engineers, physicists, and artists to address the question of whether art can be used in the dissemination of scientific understanding to new audiences in a way that gives a visceral sense of the underlying concepts. The human brain is massively complex and challenging to portray clearly. Conveying a sense of its complexity through art may inspire an interest in the brain's scientific content and inspire a new generation of neuroscientists. To produce a piece of fine art capable of sufficient detail to depict the brain at near full complexity, the piece will be executed by a technique called reflective microetching. Microetching is a high-resolution lithographic process that patterns a microtopography of periodic ridges into the surface. These ridges are engineered to reflect a point-source illumination toward a viewer when standing at a specific angle relative to the painting. Similar to darkfield microscopy, this can yield incredibly fine detail. Additionally, the angular dependence of the light adds an extra dimension that can be used to convey time, depth, or motion as the viewer walks past. The piece will feature neurons, glia, vasculature, white and gray matter, and reflectively animated circuit dynamics between areas of the brain corresponding to neural processes involved in visual self-recognition. This will infuse the piece with additional meaning, as the circuits activated within viewers' brains will be the same that are depicted in the artwork.
There is a movement afoot to turn the acronym STEM—which stands for science, technology, engineering, and mathematics—into STEAM by adding the arts. Science educators have finally begun to realize that the skills required by innovative STEM professionals include arts and crafts thinking. Visual thinking; recognizing and forming patterns; modeling; getting a "feel" for systems; and the manipulative skills learned by using tools, pens, and brushes are all demonstrably valuable for developing STEM abilities. And the National Science Foundation and the National Endowment for the Arts have gotten
Design Zone’s primary objective is to engage visitors in algebraic thinking, with a special focus on reaching a target audience of 10- to 14-year-olds and their families. The exhibition is organized into three thematic areas: art, music, and engineering. Exhibits in each area are based on real-world design challenges in which math and algebra are used. Garibay Group was contracted to conduct the summative evaluation of Design Zone. Using a mixed methods approach, data were collected at three museums hosting the Design Zone exhibition.
This project was an early example of STEAM (Science, Technology, Engineering, Art, Math) and was produced for the 2004 BLD Studios art exhibition, Time Machines, in Columbus, OH. This project included a chair and a desk made of drawers, on top of which was a audio/video work station where visitors sat and interacted with the technology by using the headphones and listening to one tape deck for instructions and then listening to music on the other while watching the TV screen with special HyperSpeks(tm). There was also a panel of photos above the TV designed to simulate time travel. The instructions explained the purpose of the exhibit and how to use the TV to tune into various channels to pick-up a variety of video static on empty UHF frequencies. The music was designed to put the visitor into a certain frame of mind. It was futuristic sounding and created using DEMI sampling, a proprietary sampling technique also created by Marshall Barnes. The intent was to set the mood. Training Session was supposed to simulate training prospective transdimensional travelers in the cognitive exercises required to deal with the psychological rigors of time/parallel universe travel. The HyperSpeks(tm) allowed the visitors to search for various shapes in the TV static on a number of selcted channels which would resemble such cosmological constructs as black holes and wormholes. The static was live and not prerecorded and so the interaction on all levels was live and in real time. Visitors were to write their observations down on paper which was provided via a note pad and pen at the exhibit. In this way, a record of their experiences existed for subsequent visitors to review. The visitors were also told to view the photo panel, which consisted of pictures taken in 1977, but not developed until 2004. As a result, the pictures were somewhat faded and all tinted pink, however, when the visitors viewed them with the HyperSpeks(tm) they appeared not only normal color, but almost as if the scenes they depicted were views outside a window. Thus, the visitor was able to travel optically back in time and see the images the way they looked when they were originally photographed.
Children feed alphabet letters to a talking baby dragon, drive a New York City fire truck, paint on a six-foot art wall, and crawl through a challenge course in PlayWorks™ at the Children's Museum of Manhattan (CMOM) in New York. Manhattan’s largest public play and learning center for early childhood marries the skills that children need to succeed in kindergarten with fun stuff that kids love. The Institute of Museum and Library Services (IMLS) funded the project through a 2006 Museums for America grant to support the museum as a center of community engagement and lifelong learning. “PlayWorks™ is a joyful place for learning science, math, reading and other things. We incorporate fun and learning into the whole design to create a scaffold of learning. Families come to the museum to supplement preschool experiences,” said Andy S. Ackerman, CMOM’s executive director. The museum also offers parents, sitters, and other care-providers guidance on engaging their children with the exhibit. Based on the concept that children’s learning and personal growth is rooted in play, the 4,000-square-foot space is divided into five learning areas: Language, Math and Physics, Arts and Science, Imagination and Dramatic Play, and Practice Play (for infants and crawlers).
Partnering with National Musical Arts, the Science Museum of Minnesota seeks to develop BioMusic, a 4,000 sq. ft. traveling exhibition that explores the origins of music in nature and the connections between music and sound of living things. This project is based on planning grant ESI-0211611 (The Music of Nature and the Nature of Music) awarded to NMA. The project is based on the emerging interdisciplinary research field of biomusic, which includes musicology plus aspects of neuroscience, biology, zoology, environmental science, physics, psychology, math and anthropology. The exhibit sections -- "Humanimal" Music; Natural Symphonies; Ancient Roots; Music, Body and Mind; and World of Music -- use both music and natural sound to explore biodiversity, cultural diversity, the physics of sound and the brain. BROADER IMPACT: The exhibition is expected to travel for at least six years, reaching some two million people in 18 communities. It is to be accompanied by a six-part radio series (Sweet Bird Classics) for young children. Because of the connection to music and many other areas of public interest, this exhibition has the potential to attract and engage new audiences to science museums and stimulate their interest in STEM.
In this article, Marjorie Schwarzer, Professor of Museum Studies at John F. Kennedy University in Berkeley, California, describes eleven of the most influential exhibitions from the 20th century, according to NAME members surveyed for her book "Riches, Rivals and Radicals: 100 Years of Museums in America."
The Science Museum of Minnesota (SMM) is collaborating with the Museum of Science in Boston (MoS), the North Carolina Museum of Life and Science in Durham (NCMLS), Explora in Albuquerque, the Center for Research in Mathematics and Science Education at San Diego State University (CRMSE), and TERC in Cambridge, MA to develop, create and evaluate "MathCore for Museums," long-term math environments that children can interact with over multiple visits and over several years. The project is prototyping and producing 12 open-source, validated interactive exhibits about proportion: fractions, ratios, similarity, scaling, and percentages, basic concepts for understanding Algebra. The eight best exhibits will be replicated for each MathCore museum and the exhibits will be supported by a limited-access website designed to support and extend repeated use of exhibits and further exploration of ratio and proportion. Selinda Research Associates will conduct a longitudinal evaluation of the project. CRSME will conduct a research study of selected exhibit prototypes to investigate when children start to work on proving relations between similarity and proportion in informal settings, the relationship between children's artwork and mathematical insight, and the roles of bodily activity in learning to see relations in similarity and proportion. Results will be disseminated in peer-reviewed publications, at professional meetings, at the Association of Science and Technology Center's RAP Sessions at the NCMLS, and through the project's website.
The California Science Center will develop an exhibition, "Abracadabra: The Science of Illusion." This will be a 6000-sq.ft. traveling exhibit. The theme, the science behind magic, will help visitors understand that magic is based on the complex interplay between sensation, perception, physical science and math concepts, culture, and the art of performance. The goal of the exhibition is to use the public's fascination with magic as a bridge to learning basic science in the area of optics, electromagnetics, simple mechanics, math, physiology and psychology. The exhibit will include seven thematic sections and an enclosed theater for live and taped performances. The exhibition will open at the California Science Center in October, 2000 and then will travel to the six science centers that participate in the Science Museum Exhibit Collaborative. It is estimated about 4 million people will view the exhibition during its national tour.