32,870 research outputs found
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Innovating Pedagogy 2015: Open University Innovation Report 4
This series of reports explores new forms of teaching, learning and assessment for an interactive world, to guide teachers and policy makers in productive innovation. This fourth report proposes ten innovations that are already in currency but have not yet had a profound influence on education. To produce it, a group of academics at the Institute of Educational Technology in The Open University collaborated with researchers from the Center for Technology in Learning at SRI International. We proposed a long list of new educational terms, theories, and practices. We then pared these down to ten that have the potential to provoke major shifts in educational practice, particularly in post-school education. Lastly, we drew on published and unpublished writings to compile the ten sketches of new pedagogies that might transform education. These are summarised below in an approximate order of immediacy and timescale to widespread implementation
FORGE: An eLearning Framework for Remote Laboratory Experimentation on FIRE Testbed Infrastructure
The Forging Online Education through FIRE (FORGE) initiative provides educators and learners in higher education with access to world-class FIRE testbed infrastructure. FORGE supports experimentally driven research in an eLearning environment by complementing traditional classroom and online courses with interactive remote laboratory experiments. The project has achieved its objectives by defining and implementing a framework called FORGEBox. This framework offers the methodology, environment, tools and resources to support the creation of HTML-based online educational material capable accessing virtualized and physical FIRE testbed infrastruc- ture easily. FORGEBox also captures valuable quantitative and qualitative learning analytic information using questionnaires and Learning Analytics that can help optimise and support student learning. To date, FORGE has produced courses covering a wide range of networking and communication domains. These are freely available from FORGEBox.eu and have resulted in over 24,000 experiments undertaken by more than 1,800 students across
10 countries worldwide. This work has shown that the use of remote high- performance testbed facilities for hands-on remote experimentation can have a valuable impact on the learning experience for both educators and learners. Additionally, certain challenges in developing FIRE-based courseware have been identified, which has led to a set of recommendations in order to support the use of FIRE facilities for teaching and learning purposes
From Social Simulation to Integrative System Design
As the recent financial crisis showed, today there is a strong need to gain
"ecological perspective" of all relevant interactions in
socio-economic-techno-environmental systems. For this, we suggested to set-up a
network of Centers for integrative systems design, which shall be able to run
all potentially relevant scenarios, identify causality chains, explore feedback
and cascading effects for a number of model variants, and determine the
reliability of their implications (given the validity of the underlying
models). They will be able to detect possible negative side effect of policy
decisions, before they occur. The Centers belonging to this network of
Integrative Systems Design Centers would be focused on a particular field, but
they would be part of an attempt to eventually cover all relevant areas of
society and economy and integrate them within a "Living Earth Simulator". The
results of all research activities of such Centers would be turned into
informative input for political Decision Arenas. For example, Crisis
Observatories (for financial instabilities, shortages of resources,
environmental change, conflict, spreading of diseases, etc.) would be connected
with such Decision Arenas for the purpose of visualization, in order to make
complex interdependencies understandable to scientists, decision-makers, and
the general public.Comment: 34 pages, Visioneer White Paper, see http://www.visioneer.ethz.c
The Boston University Photonics Center annual report 2013-2014
This repository item contains an annual report that summarizes activities of the Boston University Photonics Center in the 2013-2014 academic year. The report provides quantitative and descriptive information regarding photonics programs in education, interdisciplinary research, business innovation, and technology development. The Boston University Photonics Center (BUPC) is an interdisciplinary hub for education, research, scholarship, innovation, and technology development associated with practical uses of light.This annual report summarizes activities of the Boston University Photonics Center in the 2013–2014 academic year.This has been a good year for the Photonics Center. In the following pages, you will see that the center’s faculty received prodigious honors and awards, generated more than 100 notable scholarly publications in the leading journals in our field, and attracted 20M in research funding for the University, are indicative of the breadth of Photonics Center research interests: from fundamental modeling of optoelectronic materials to practical development of cancer diagnostics, from exciting new discoveries in optogenetics for understanding brain function to the achievement of world-record resolution in semiconductor circuit microscopy. Our community welcomed an auspicious cohort of new faculty members, including a newly hired assistant professor and a newly hired professor (and Chair of the Mechanical Engineering Department). The Industry/University Cooperative Research Center—the centerpiece of our translational biophotonics program—continues to focus on advancing the health care and medical device industries, and has entered its fourth year of operation with a strong record of achievement and with the support of an enthusiastic industrial membership base
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Framing professional competencies for systems thinking in practice: final report of an action research eSTEeM inquiry
The Open University eSTEeM project (The OU Centre for STEM Pedagogy) was a 12-month inquiry beginning March 2017 building on an initial eSTEeM project (2014-2016) entitled ‘Enhancing Systems Thinking in Practice in the Workplace’ reported on in Reynolds et al (2016). The initial report highlighted the challenges of enacting systems thinking in practice (STiP) in the workplace after qualifying with STiP core modules at The OU. Expressions of interest were manifest amongst systems thinking practitioners and employers for having some kind of formalised externally validated ‘competency framework’ for professional recognition of systems thinking in practice.
The primary aim of the inquiry was to provide STiP alumni with externally recognised institutionalised professional backing for their newly acquired skill-sets associated with systems thinking. The project aimed to design a learning system – through the idea of an action learning lab – for developing a competency framework associated with systems thinking in practice.
The project was carried out by a core team of three academics – Reynolds, Shah, and van Ameijde, associated with the Applied Systems Thinking in Practice (ASTiP) Group in the School of Engineering and Innovation, along with advice and support from other ASTiP colleagues – most notably Ray Ison and Chris Blackmore.
The inquiry comprised some desktop research on competency framings, a series of online interviews, the drafting of an interim report, a video recording of employee/ employer interaction regarding application of STiP competencies in the workplace, a workshop held in London Regional Office in June 2017, and follow-up reporting and conversations arising from the workshop. One significant outcome from this activity led to ideas and consultations with Employer representatives, professional bodies and the Institute for Apprenticeships to initiate a Trailblazing Committee for a new Systems Thinking Practitioner apprenticeship Standard
Toward a Standardized Strategy of Clinical Metabolomics for the Advancement of Precision Medicine
Despite the tremendous success, pitfalls have been observed in every step of a clinical metabolomics workflow, which impedes the internal validity of the study. Furthermore, the demand for logistics, instrumentations, and computational resources for metabolic phenotyping studies has far exceeded our expectations. In this conceptual review, we will cover inclusive barriers of a metabolomics-based clinical study and suggest potential solutions in the hope of enhancing study robustness, usability, and transferability. The importance of quality assurance and quality control procedures is discussed, followed by a practical rule containing five phases, including two additional "pre-pre-" and "post-post-" analytical steps. Besides, we will elucidate the potential involvement of machine learning and demonstrate that the need for automated data mining algorithms to improve the quality of future research is undeniable. Consequently, we propose a comprehensive metabolomics framework, along with an appropriate checklist refined from current guidelines and our previously published assessment, in the attempt to accurately translate achievements in metabolomics into clinical and epidemiological research. Furthermore, the integration of multifaceted multi-omics approaches with metabolomics as the pillar member is in urgent need. When combining with other social or nutritional factors, we can gather complete omics profiles for a particular disease. Our discussion reflects the current obstacles and potential solutions toward the progressing trend of utilizing metabolomics in clinical research to create the next-generation healthcare system.11Ysciescopu
The Boston University Photonics Center annual report 2013-2014
This repository item contains an annual report that summarizes activities of the Boston University Photonics Center in the 2013-2014 academic year. The report provides quantitative and descriptive information regarding photonics programs in education, interdisciplinary research, business innovation, and technology development. The Boston University Photonics Center (BUPC) is an interdisciplinary hub for education, research, scholarship, innovation, and technology development associated with practical uses of light.This annual report summarizes activities of the Boston University Photonics Center in the 2013–2014 academic year.This has been a good year for the Photonics Center. In the following pages, you will see that the center’s faculty received prodigious honors and awards, generated more than 100 notable scholarly publications in the leading journals in our field, and attracted 20M in research funding for the University, are indicative of the breadth of Photonics Center research interests: from fundamental modeling of optoelectronic materials to practical development of cancer diagnostics, from exciting new discoveries in optogenetics for understanding brain function to the achievement of world-record resolution in semiconductor circuit microscopy. Our community welcomed an auspicious cohort of new faculty members, including a newly hired assistant professor and a newly hired professor (and Chair of the Mechanical Engineering Department). The Industry/University Cooperative Research Center—the centerpiece of our translational biophotonics program—continues to focus on advancing the health care and medical device industries, and has entered its fourth year of operation with a strong record of achievement and with the support of an enthusiastic industrial membership base
Implementation of Systems Engineering Approach in Academic Projects: Software Defined Radio Technology Development as a Case Study
Each year, federal and private agencies spend billions of dollars on research projects that academic institutions conduct for them. However, the communication language between these agencies as clients and academia as hosts, is not very efficient and well-established. This has resulted in lack of clarity in clients’ description of what exactly to be expected and in hosts’ description of their capabilities and challenges. In addition, many of these projects are essentially interdisciplinary and demand the involvement of diverse research teams from different university departments. Lack of cohesive collaboration among these diverse teams results in mismatches between different compartments of project output, and consequently, generation of superfluous product prototypes. Finally, for their real-time tracking and later retrieval, the current situation of documentation of academic projects needs to be significantly altered. We suggest that the presence of a systems engineering team should be an indispensable part of a large academic research project, in order to monitor and manage the various aspects and phases from initiation to completion.For this purpose, we proposed a systems engineering model specific for academic research projects, which considers both strengths and challenges of universities as host research institutes. As a case study, we applied this proposed systems engineering approach on a NASA-funded project at Morgan State University (MSU) which was about design and implementation of software defined radio (SDR) for space exploration. Application of this model significantly improved the professional dialogue and technical clarifications between NASA and MSU partners, as well as within MSU teams. Moreover, the sub-system compatibility among different modules of the implemented product was notably enhanced. Overall, application of systems engineering approach in academic projects can result in mutual benefits for the institution and either federal or private client
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