Blended Courses Across the Curriculum: What Works and What Does Not

Recent hype around online and blended courses touts the benefits of immediate student feedback, flexible pace, adaptive learning, and better utility of classroom space. Here we aim to summarize the results of a 3-year pilot study using blended courses across the quantitative science curriculum (Mathematics, Statistics and Computer Science), in both upper and lower division, major and GE courses. We present findings on student attitudes towards this format, most helpful course components, time on task, progress on learning outcomes and faculty perspectives. This summary can be used to inform best practices in hybrid design, implementation and faculty expectations in the quantitative sciences

The pedagogy of design and technology at Xavier University of Louisiana, New Orleans

Abstract. Xavier University of Louisiana (XULA) is a Science, Technology, Engineering, and Mathematics (STEM) university located in New Orleans, Louisiana. As a Historically Black University (HBCU), the university serves a diverse community of students in which many are first-generation, college graduates. Students enrolled in Design courses at XULA are studying in Bachelor of Science and Bachelor of Art programs and majoring in subjects such as Computer Science, Physics, Mass Communication, Art, Business, and Science. The interdisciplinary student environment offers a unique opportunity for collaboration and peer learning, whereby students are able to share diverse perspectives on a topic by relating design processes to their fields of study. In laboratory practice, students work on independent and collaborative projects in Product Design and User Experience by developing work through a design process from ideation to production

“It’s What We Use as a Community”: Exploring Students’ STEM Characterizations In Two Montessori Elementary Classrooms

University of Minnesota M.A. thesis. June 2017. Major: Education, Curriculum and Instruction. Advisor: Julie Brown. 1 computer file (PDF); ix, 255 pages.Integrated science, technology, engineering, and mathematics (STEM) education promises to enhance elementary students’ engagement in science and related fields and to cultivate their problem-solving abilities. While STEM has become an increasingly popular reform initiative, it is still developing within the Montessori education community. There is limited research on STEM teaching and learning in Montessori classrooms, particularly from student perspectives. Previous studies suggest productive connections between reform-based pedagogies in mainstream science education and the Montessori method. Greater knowledge of this complementarity, and student perspectives on STEM, may benefit both Montessori and non-Montessori educators. This instrumental case study of two elementary classrooms documented student characterizations of aspects of STEM in the context of integrated STEM instruction over three months in the 2016-2017 school year. Findings show that the Montessori environment played an important role, and that students characterized STEM in inclusive, agentive, connected, helpful, creative, and increasingly critical ways. Implications for teaching and future research offer avenues to envision STEM education more holistically by leveraging the moral and humanistic aspects of Montessori philosophy

Student experiences of technology integration in school subjects: A comparison across four middle schools

This research examined student perspectives on their in-school, subject specific, technology use in four U.S. public schools. Considering students’ perspectives may provide a significant reframing of adult-created rhetoric of the utopian power of digital technologies for changing teaching and learning. A survey and focus group interviews were administered to 6th and 7th students (n=1,544) in four public middle schools, with varying demographics, that rely on local funding. These four schools revealed moderate use of many well-established digital technologies, such as word processing, presentation software, and quiz games. Students voiced outright hatred for teacher-directed PowerPoint-supported lectures, the most prominent technology activity students experienced, yet reported enjoying creation activities. The students in the rural school with a Hispanic-majority and high economically disadvantaged population reported much lower technology use. Discussion frame the digital inequities in the four schools and emphasizes the need for awareness and inclusion of students’ digital experiences to form any trajectory toward establishing digital equity and learning in schools

Alternative Modes for Teaching Mathematical Problem Solving: An Overview

Various modes are proffered as alternatives for teaching mathematical problem solving. Each mode is described briefly, along with general purposes, advantages and disadvantages. Combinations of modes are suggested; general issues identified; recommendations offered; and feedback from teachers summarized

From Kansas to Queensland: Global learning in preservice elementary teacher education

Communication of information between groups of humans has been extended through out history progressing from smoke signals, drum beats, message couriers, post, telegraph, telephone and now the ICT. The time between the utterance of a message and the reception of that message has progressively decreased. We are now able to communicate relatively cheaply, simultaneously sharing and responding to ideas and thoughts on a scale never previously possible. Although the technology exists to make possible easy access to people in all parts of the world, we still lack understandings of the aspirations and sensitivities of other cultures with whom we can communicate. This project supported pre-service elementary teachers in two countries – Australia and the United States – to engage in collaborative learning through Internet communications. The purpose of the project was to develop greater understanding of other’s cultures, and practices in teaching elementary students. Students attending an Australian preservice primary science methods course were matched with a cohort of undergraduate preservice elementary student teachers from a university in the United States studying an integrated mathematics science methods course. Over a six-week period the students engaged in the computer-mediated communication and were encouraged to learn about mutual cultural practices and primary/elementary science education in both countries. The outcomes demonstrated that students involved in the project benefited from an array of different and enriching learning experiences. Students benefited through enhanced understanding of the teaching of science and an appreciation of the common problems confronting science education in both countries. However, there was little engagement in debate or discussion of individual differences and the cultural context of each other’s country even when opportunities presented themselves. Nevertheless, the on-line tasks provided the pre-service teachers with the experience and confidence to engage their own students in similar global learning initiatives when they become teachers

Digital technology in mathematics education: Why it works (or doesn't)

The integration of digital technology confronts teachers, educators and researchers with many questions. What is the potential of ICT for learning and teaching, and which factors are decisive in making it work in the mathematics classroom? To investigate these questions, six cases from leading studies in the field are described, and decisive success factors are identified. This leads to the conclusion that crucial factors for the success of digital technology in mathematics education include the design of the digital tool and corresponding tasks exploiting the tool's pedagogical potential, the role of the teacher and the educational context

Multinational perspectives on information technology from academia and industry

As the term \u27information technology\u27 has many meanings for various stakeholders and continues to evolve, this work presents a comprehensive approach for developing curriculum guidelines for rigorous, high quality, bachelor\u27s degree programs in information technology (IT) to prepare successful graduates for a future global technological society. The aim is to address three research questions in the context of IT concerning (1) the educational frameworks relevant for academics and students of IT, (2) the pathways into IT programs, and (3) graduates\u27 preparation for meeting future technologies. The analysis of current trends comes from survey data of IT faculty members and professional IT industry leaders. With these analyses, the IT Model Curricula of CC2005, IT2008, IT2017, extensive literature review, and the multinational insights of the authors into the status of IT, this paper presents a comprehensive overview and discussion of future directions of global IT education toward 2025

An Overview of the New ACM/IEEE Information Technology Curricular Framework

ACM and IEEE have developed a curricular report titled, “Information Technology Curricula 2017: Curriculum Guidelines for Baccalaureate Degree Programs in Information Technology,” known also as IT2017. The development of this report has received worldwide content contributions from industry and academia through surveys as well as many international conferences and workshops. An open online publication of the report was made available in December 2017. This paper presents a digest of the content of the report, the IT curricular framework, and suggestions for its use in developing new information technology programs or enhancing existing ones. The heart of the IT curricular framework is a set of competencies identified through knowledge, skills, and dispositions, as supported by pedagogical research. The paper also describes ways in which institutions could use the curricular framework not only to develop information technology degree programs, but also to improve and enhance related computing programs

The worldwide use of computers : a description of main trends

This paper examines some of the main findings from the IEA Computers in Education survey. The results show that with respect to the future of computers in education there is reason for optimism as well as for pessimism. The optimistic part of the story is that new technologies in the form of computers are nowadays available for many schools in most so-called developed countries, and that despite the complexity of this innovation educational practitioners and students are still very enthusiastic about this technology. The pessimistic part is that there is still much inequity of access to computers. Once computers are available they tend to be used most frequently as an add-on to the existing curriculum. It is probably this lack of integration of computers in existing curricula which is most challenging in determining our agenda for the future