In October 2017, the PBS NewsHour team produced a week and a half of opioid-related content, including several online explainers, which presented the opportunity for a natural experiment for the Experiments in Transmedia project.
Knology (formerly New Knowledge Organization Ltd.) conducted a two-wave research study to advance understanding of the youth audience’s knowledge and news consumption on the topic.
The first wave of the study, conducted in September 2017, provides a baseline. The content aired in October 2017, and the second wave of the study, conducted in November 2017, asked a
Information visualization could be used to leverage the credibility of displayed scientific data. However, little was known about how display characteristics interact with individuals' predispositions to affect perception of data credibility. Using an experiment with 517 participants, we tested perceptions of data credibility by manipulating data visualizations related to the issue of nuclear fuel cycle based on three characteristics: graph format, graph interactivity, and source attribution. Results showed that viewers tend to rely on preexisting levels of trust and peripheral cues, such as
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TEAM MEMBERS:
Nan LiDominique BrossardDietram ScheufelePaul WilsonKathleen Rose
The characteristics of interaction and dialogue implicit in the Web 2.0 have given rise to a new scenario in the relationship between science and society. The aim of this paper is the development of an evaluation tool scientifically validated by the Delphi method that permits the study of Internet usage and its effectiveness for encouraging public engagement in the scientific process. Thirty four indicators have been identified, structured into 6 interrelated criteria conceived for compiling data that help to explain the role of the Internet in favouring public engagement in science.
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TEAM MEMBERS:
Lourdes LopezMaria Dolores Olvera-Lobo
Science permeates nearly every facet of human life and civilization. However, in an age of media oversaturation, it has been increasingly easier for pseudoscientific information to be disseminated among the masses, especially by those with a political agenda. In his book, ‘Not a Scientist: How Politicians Mistake, Misrepresent, and Utterly Mangle Science’, author Dave Levitan creates a guidebook for spotting and debunking unscientific ideas in the political sphere, a vital tool in the Information Age.
Participants in this study reported a variety of resources used in the past to learn to code in Apex, including online tutorials, one-day classes sponsored by Salesforce, and meet-up groups focused on learning. They reported various difficulties in learning through these resources, including what they viewed as the gendered nature of classes where the men already seemed to know how to code—which set a fast pace for the class, difficulty in knowing “where to start” in their learning, and a lack of time to practice learning due to work and family responsibilities. The Coaching and Learning Group
This book is a beginners' guide to science journalism, explaining the 21st century journalistic process, from generating story ideas to creating multimedia content when the story's written, taking in research and writing structures along the way. While many of the chapters are introductory, the book also covers topics also likely to be of interest to more experienced writers, such as storytelling techniques and investigative journalism. Readers are introduced to important debates in the field, including the role that science journalism plays; whether it is a form of `infotainment', or whether
Climate change is a global risk as its causes and effects are not limited to national borders, but the risks and the responsibility are not evenly spread [Beck, 2009]. Pakistan is facing especially severe impacts in the form of disasters, floods, droughts, rising temperatures, cyclones and rising sea levels due to global emissions, despite its national emissions being nominal and accounting for only 0.46% of worldwide emissions [World Bank, 2018]. Ironically, the level of public awareness of climate change is low in Pakistan compared to not only advanced countries, but also to other countries
This INSPIRE award is partially funded by the Cyber-Human Systems Program in the Division of Information and Intelligent Systems in the Directorate for Computer Science and Engineering, the Gravitational Physics Program in the Division of Physics in the Directorate for Mathematical and Physical Sciences, and the Office of Integrative Activities.
This innovative project will develop a citizen science system to support the Advanced Laser Interferometer Gravitational wave Observatory (aLIGO), the most complicated experiment ever undertaken in gravitational physics. Before the end of this decade it will open up the window of gravitational wave observations on the Universe. However, the high detector sensitivity needed for astrophysical discoveries makes aLIGO very susceptible to noncosmic artifacts and noise that must be identified and separated from cosmic signals. Teaching computers to identify and morphologically classify these artifacts in detector data is exceedingly difficult. Human eyesight is a proven tool for classification, but the aLIGO data streams from approximately 30,000 sensors and monitors easily overwhelm a single human. This research will address these problems by coupling human classification with a machine learning model that learns from the citizen scientists and also guides how information is provided to participants. A novel feature of this system will be its reliance on volunteers to discover new glitch classes, not just use existing ones. The project includes research on the human-centered computing aspects of this sociocomputational system, and thus can inspire future citizen science projects that do not merely exploit the labor of volunteers but engage them as partners in scientific discovery. Therefore, the project will have substantial educational benefits for the volunteers, who will gain a good understanding on how science works, and will be a part of the excitement of opening up a new window on the universe.
This is an innovative, interdisciplinary collaboration between the existing LIGO, at the time it is being technically enhanced, and Zooniverse, which has fielded a workable crowdsourcing model, currently involving over a million people on 30 projects. The work will help aLIGO to quickly identify noise and artifacts in the science data stream, separating out legitimate astrophysical events, and allowing those events to be distributed to other observatories for more detailed source identification and study. This project will also build and evaluate an interface between machine learning and human learning that will itself be an advance on current methods. It can be depicted as a loop: (1) By sifting through enormous amounts of aLIGO data, the citizen scientists will produce a robust "gold standard" glitch dataset that can be used to seed and train machine learning algorithms that will aid in the identification task. (2) The machine learning protocols that select and classify glitch events will be developed to maximize the potential of the citizen scientists by organizing and passing the data to them in more effective ways. The project will experiment with the task design and workflow organization (leveraging previous Zooniverse experience) to build a system that takes advantage of the distinctive strengths of the machines (ability to process large amounts of data systematically) and the humans (ability to identify patterns and spot discrepancies), and then using the model to enable high quality aLIGO detector characterization and gravitational wave searches
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TEAM MEMBERS:
Vassiliki KalogeraAggelos KatsaggelosKevin CrowstonLaura TrouilleJoshua SmithShane LarsonLaura Whyte
Twin Cities PBS BRAINedu: A Window into the Brain/Una ventana al cerebro, is a national English/Spanish informal education project providing culturally competent programming and media resources about the brain’s structure and function to Hispanic middle school students and their families. The project responds to the need to eliminate proven barriers to Hispanic students’ STEM/neuroscience education, increase Hispanic participation in neuroscience and mental health careers and increase Hispanic utilization of mental health resources.
The program’s goals are to engage Hispanic learners and families by
empowering informalSTEM educators to provide culturally competent activities about the brain’s structure and function;
demonstrating neuroscience and mental health career options; and
reducing mental health stigma, thus increasing help-seeking behavior.
The hypothesis underpinning BRAINedu’s four-year project plan is that participating Hispanic youth and families will be able to explain how the brain works and describe specific brain disorders; demonstrate a higher level of interest of neuroscience and mental health careers and be more willing to openly discuss and seek support for brain disorders and mental health conditions.
To achieve program goals, Twin Cities PBS (TPT) will leverage existing partnerships with Hispanic-serving youth educational organizations to provide culturally competent learning opportunities about brain health to Hispanic students and families. TPT will partner with neuroscience and mental health professionals, cultural competency experts and Hispanic-serving informal STEM educators to complete the following objectives:
Develop bilingual educational resources for multigenerational audiences;
Provide professional development around neuroscience education to informal educators, empowering them to implement programming with Hispanic youth and families, and
Develop role model video profiles of Hispanic neuroscience professionals, and help partner organizations produce autobiographical student videos.
We will employ rigorous evaluation strategies to measure the project’s impact on Hispanic participants: a) understanding of neuroscience and brain health, particularly around disorders that disproportionately affect the Hispanic community; b) motivation to pursue neuroscience or mental health career paths; and c) mental health literacy and help-seeking behavior. The project will directly reach 72 Hispanic-serving informal STEM educators and public health professionals, and 200 children and 400 parents in underserved urban, suburban and rural communities nationwide.
The New York Hall of Science (NYSCI) will develop, test, market, and disseminate an interactive graphic novel iBook that will use the interests of young people (ages 10–14) in animals and comics to engage them in learning about health and clinical research. Provisionally called “Transmission: Astonishing Tales of Human-Animal Diseases,” the project represents a new approach to engaging young people in biomedical science learning.
Graphic novels are one of the fastest growing categories in publishing and bookselling, and today, they are significantly more sophisticated than the comics that came before them. They are also enormously popular among young people. The proposed graphic novel iBook will focus on the diseases that humans and animals share and pass between them (sometimes to devastating consequences), from Ebola, bird flu, and West Nile disease to influenza, measles, and pneumonia. Moreover, like many other contemporary graphic novels, it will address a pressing issue of the day—amely, the growth of zoonotic and anthropozoonotic diseases.
The iBook will be developed in a digital, interactive format (a growing trend within the genre) and, like many graphic novel titles, will take a mystery and forensic crime approach to exploring its content. Ultimately, Transmission will become a national model for conveying biomedical understanding through the use of up-to-the-minute interactive iBook technologies and an engaging graphic novel format.
For public health to improve, all sectors of society much have access to the highest quality health science news and information possible. How that information is translated, packaged and disseminated is important: the stories matter. Our journalism and mentoring program will grow the health science literacy of the nation by building the next generation of science communicators, ensuring that cadre of youth from historically disadvantaged groups have the discipline, creativity and critical thinking skills needed to be successful health science-literate citizens and advocates within their own communities.
Using a combination of youth-generated videos, broadcast reporting and online curriculum resources, PBS NewsHour will engineer successful educational experiences to engage students from all backgrounds, and particularly underserved populations, to explore clinical, biomedical, and behavioral research. The PBS NewsHour’s Student Reporting Labs program, currently in 41 states, will create 10 health science reporting labs to produce unique news stories that view health and science topics from a youth perspective. We will incorporate these videos into lesson plans and learning tools disseminated to the general public, educators and youth media organizations. Students will be supported along the way with curricula and mentorship on both fundamental research and the critical thinking skills necessary for responsible journalism. This process will ensure the next generation includes citizens who are effective science communicators and self-motivated learners with a deep connection to science beyond the textbook and classroom.
PBS NewsHour will develop a STEM-reporting curriculum to teach students important research skills. The program will include activities that expose students to careers in research, highlight a diverse assortment of pioneering scientists as role models and promote internship opportunities. The resources will be posted on the PBS NewsHour Extra site which has 170,000 views per month and our partner sites on PBS Learning Media and Share My Lesson—the two biggest free education resource sites on the web—thus greatly expanding the potential scope of our outreach and impact.
NewsHour broadcast topics will be finalized through our advisory panel and the researchers interviewed for the stories will be selected for their expertise and skills as effective science communicators, as well as their diversity and ability to connect with youth. Finally, we will launch an outreach and community awareness campaign through strategic partnerships and coordinated cross promotion of stories through social media platforms.
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.