With funding from the National Science Foundation, NOVA/WGBH Boston with the participation of 14 U.S. and 4 international science museums have produced an IMAX/OMNIMAX film titled, Special Effects. The 40-minute film shows the techniques and methods that special effects filmmakers use to create movie illusions. Multimedia Research implemented a summative evaluation with students focused on the following major outcomes: To what extent did the program appeal to student viewers? To what extent did the program achieve its intended viewing goals? Did the implementation of school-based activities
Research on mathematical reasoning and learning has long been a central part of the classroom and formal education literature (e.g., National Research Council, 2001, 2005). However, much less attention has been paid to how children and adults engage with and learn about math outside of school, including everyday settings and designed informal learning environments, such as interactive math exhibits in science centers. With the growing recognition of the importance of informal STEM education (National Research Council, 2009, 2015), researchers, educators, and policymakers are paying more
Making, tinkering, and other informal design and engineering experiences offer rich opportunities to engage
children and adults in mathematics and build mathematical skills, knowledge, and interests. But how can educators
successfully integrate mathematics into these experiences? One approach to answering this question is to better understand how children and adults engage with and think about mathematics outside of school, in every day and informal learning environments. As part of the NSF-funded Math in
the Making project, Pattison, Rubin, and Wright (2016) synthesized the research on
Although there is a growing body of research on mathematics in informal learning environments (Pattison, Rubin, & Wright, 2016; Rubin, Garibay, & Pattison, 2016), less has been done to understand how math can be integrated into other informal STEM education settings or topics, and how this integration might engage those who do not already have positive attitudes about math. Over the last decade there has been a proliferation of out-of-school environments that foster building, making, tinkering, and design activities (Bevan, Gutwill, Petrich, & Wilkinson, 2015; Vossoughi, Escudé, Kong, & Hooper
Novice teachers require support in learning to attend and respond to students’ thinking as expert teachers do. Video clubs in which groups of teachers respond to videos of one another’s classrooms can help. Van Es and Sherin describe how a video club helped teachers make space for student thinking to emerge, probe students’ understanding, and learn from their students while teaching.
Lobato, Rhodehamel, and Hohensee investigated how learners “transferred” knowledge from one situation to another. They found that both individual cognition and the social organization of the class drove the learners’ process of selecting, interpreting, and working with particular features of mathematical information. They also found the social arrangements of the class influenced what pieces of information students noticed and focused on.
This poster was presented at the 2016 Advancing Informal STEM Learning (AISL) PI Meeting held in Bethesda, MD on February 29-March 2. Using a combination of Peg + Cat, an animated math-based PBS television series for preschoolers; professional development (PD); family engagement resources; and the existing infrastructure of a regional Head Start system, this project aims to increase participating educators’ and families’ comfort and engagement with mathematics.
This poster was presented at the 2016 Advancing Informal STEM Learning (AISL) PI Meeting held in Bethesda, MD on February 29-March 2. This project develops and researches the integration of Peg + Cat (an animated, math-based PBS television series for preschoolers), accompanying digital media, and early childhood educator professional development (PD). PD is designed to enhance educators’ abilities to support preschoolers’ social-emotional learning in the context of math activities, and in turn, their interest and engagement in math. The project also includes recommendations for engaging
This poster was presented at the 2016 Advancing Informal STEM Learning (AISL) PI Meeting held in Bethesda, MD on February 29-March 2. After-School Math Plus (ASM+) combines inquiry-based, hands-on activities connected to students’ interests outside
of school; standards-aligned skill development; strong focus on reaching groups underrepresented in math; role models and career exploration; and family involvement.
Formal readings and lectures are effective at delivering explanations, but the information they impart can be so densely packed and de-contextualized that students may not make full sense of the content. Arena and Schwartz found that video games have the potential to unlock the expository content delivered by lectures, textbooks, and diagrams.
Researchers examined whether engineering activities and lessons can help students apply science and math content in real-world contexts and gain insights into the professional activities and goals of engineers.
The authors of this study investigated the educational potential of a digital math game called Zombie Division in an elementary classroom. Habgood & Ainsworth were interested in the effect of what they called “intrinsic integration” –linking the video game’s core mechanics of play to the educational content. The idea is linked to the field of research called intrinsic motivation, in which the only reward is pleasure in the activity itself. The researchers argue that, while a game like MathBlaster is fun, it does not embody the mathematics lesson as an intrinsic part of game play.