The Whaling Museum & Education Center will expand its educational programming to benefit underserved and high-risk students in grades 2 to 5, as well as their teachers and families. The museum will develop, implement, market, and evaluate core components of its programming to reach nearly 3,000 students and 50 teachers. Museum educators will present hands-on activities in nearby schools, using real and replica artifacts and other learning materials. They will also deliver workshops for teachers at the museum to help them incorporate primary resources from the museum's collection into their curricula. A family day event will showcase what students learned from the in-class visit through displays of art projects and science posters. Other project activities will include free afterschool library programs exploring STEAM and history topics and an increase in the number of scholarships to the museum's summer camp program.
The Saginaw Chippewa Indian Tribe of Michigan's Ziibiwing Center of Anishinabe Culture and Lifeways will organize a four-day educational symposium to build a better understanding of Native American culture and history. The project will begin with a forum to foster dialogue on the 200th anniversary of the Treaty of Saginaw. The forum will discuss the treaty's impact on sovereignty and relationships between natives and non-natives and the loss of continuity of language, culture, and the practice of traditional art forms. The forum will include representatives from the 25 tribes whose children attended the Mount Pleasant Indian Industrial Boarding School. The representatives will share cultural stories and traditional methods through birch bark, black ash, elm and sweet grass basket making. The symposium will conclude on Michigan Indian Day with science, technology, engineering, art and math (STEAM) activities for area students.
Production of an immersive website exploring the history, culture, and archaeology of the Giza plateau.
The Giza Project at Harvard University plans to build the full-scale version of its forthcoming public website, Digital Giza. Using the tools of the future to study the past, this free online resource will integrate diverse primary documentation from over 100 years of international archaeological research in Egypt with a scientifically-informed 3D immersive computer model of the whole Giza Plateau, including the pyramids, temples, settlements, and surrounding cemeteries. Through various “digital archaeology experiences,” visitors to the site will engage with new forms of interpretation and story-telling based on Giza materials digitally embedded and clearly contextualized in their original spatial settings. The Giza Project’s ultimate deliverable will be a powerful new online education and research tool for the world community at all levels of expertise: an interactive website and virtual environment encouraging exploration into Egyptological, historical, and broader humanities themes.
This Research Advanced by Interdisciplinary Science and Engineering (RAISE) project is supported by the Division of Research on Learning in the Education and Human Resources Directorate and by the Division of Computing and Communication Foundations in the Computer and Information Science and Engineering Directorate. This interdisciplinary project integrates historical insights from geometric design principles used to craft classical stringed instruments during the Renaissance era with modern insights drawn from computer science principles. The project applies abstract mathematical concepts toward the making and designing of furniture, buildings, paintings, and instruments through a specific example: the making and designing of classical stringed instruments. The research can help instrument makers employ customized software to facilitate a comparison of historical designs that draws on both geometrical proofs and evidence from art history. The project's impacts include the potential to shift in fundamental ways not only how makers think about design and the process of making but also how computer scientists use foundational concepts from programming languages to inform the representation of physical objects. Furthermore, this project develops an alternate teaching method to help students understand mathematics in creative ways and offers specific guidance to current luthiers in areas such as designing the physical structure of a stringed instrument to improve acoustical effect.
The project develops a domain-specific functional programming language based on straight-edge and compass constructions and applies it in three complementary directions. The first direction develops software tools (compilers) to inform the construction of classical stringed instruments based on geometric design principles applied during the Renaissance era. The second direction develops an analytical and computational understanding of the art history of these instruments and explores extensions to other maker domains. The third direction uses this domain-specific language to design an educational software tool. The tool uses a calculative and constructive method to teach Euclidean geometry at the pre-college level and complements the traditional algebraic, proof-based teaching method. The representation of instrument forms by high-level programming abstractions also facilitates their manufacture, with particular focus on the arching of the front and back carved plates --- of considerable acoustic significance --- through the use of computer numerically controlled (CNC) methods. The project's novelties include the domain-specific language itself, which is a programmable form of synthetic geometry, largely without numbers; its application within the contemporary process of violin making and in other maker domains; its use as a foundation for a computational art history, providing analytical insights into the evolution of classical stringed instrument design and its related material culture; and as a constructional, computational approach to teaching geometry.
This project is funded by the National Science Foundation's (NSF's) Advancing Informal STEM Learning (AISL) program, which supports innovative research, approaches, and resources for use in a variety of learning settings.