This computer-based lab manual contains experiments in mechanics, thermodynamics, E&M, and optics using hardware and software designed to enhance readers' understanding of calculus-based physics concepts. It uses an active learning cycle, including concept overviews, hypothesis-testing, prediction-making, and investigations.
RealTime Physics is a series of introductory laboratory modules that use computer data acquisition tools (microcomputer-based lab or MBL tools) to help students develop important physics concepts while acquiring vital laboratory skills. Besides data acquisition, computers are used for basic mathematical modeling, data analysis, and simulations. There are 4 RealTime Physics modules: Module 1: Mechanics, Module 2: Heat and Thermodynamics, Module 3: Electricity and Magnetism, and Module 4: Light and Optics.
The authors of RealTime Physics Active Learning Laboratories, Module 1: Mechanics, 3rd Edition - David Sokoloff, Priscilla Laws, and Ron Thornton - have been pioneers in the revolution of the physics industry. In this edition, they provide a set of labs that utilize modern lab technology to provide hands-on information, as well as an empirical look at several new key concepts. They focus on the teaching/learning issues in the lecture portion of the course, as well as logistical lab issues such as space, class size, staffing, and equipment maintenance. Issues similar to those in the lecture have to with preparation and willingness to study.
RealTime Physics is a series of introductory laboratory modules that use computer data acquisition tools (microcomputer-based lab or MBL tools) to help students develop important physics concepts while acquiring vital laboratory skills. Besides data acquisition, computers are used for basic mathematical modeling, data analysis, and simulations. There are 4 RealTime Physics modules: Module 1: Mechanics, Module 2: Heat and Thermodynamics, Module 3: Electricity and Magnetism, and Module 4: Light and Optics.
RealTime Physics is a series of introductory laboratory modules that use computer data acquisition tools (microcomputer-based lab or MBL tools) to help students develop important physics concepts while acquiring vital laboratory skills. Besides data acquisition, computers are used for basic mathematical modeling, data analysis, and simulations. There are 4 RealTime Physics modules: Module 1: Mechanics, Module 2: Heat and Thermodynamics, Module 3: Electricity and Magnetism, and Module 4: Light and Optics.
Adapting to a Changing World was commissioned by the National Science Foundation to examine the present status of undergraduate physics education, including the state of physics education research, and, most importantly, to develop a series of recommendations for improving physics education that draws from the knowledge we have about learning and effective teaching. Our committee has endeavored to do so, with great interest and more than a little passion. The Committee on Undergraduate Physics Education Research and Implementation was established in 2010 by the Board on Physics and Astronomy of the National Research Council. This report summarizes the committee's response to its statement of task, which requires the committee to produce a report that identifies the goals and challenges facing undergraduate physics education and identifies how best practices for undergraduate physics education can be implemented on a widespread and sustained basis, assess the status of physics education research (PER) and discuss how PER can assist in accomplishing the goal of improving undergraduate physics education best practices and education policy.
This book explores in detail the role of laboratory work in physics teaching and learning. Compelling recent research work is presented on the value of experimentation in the learning process, with description of important research-based proposals on how to achieve improvements in both teaching and learning. The book comprises a rigorously chosen selection of papers from a conference organized by the International Research Group on Physics Teaching (GIREP), an organization that promotes enhancement of the quality of physics teaching and learning at all educational levels and in all contexts. The topics covered are wide ranging. Examples include the roles of open inquiry experiments and advanced lab experiments, the value of computer modeling in physics teaching, the use of web-based interactive video activities and smartphones in the lab, the effectiveness of low-cost experiments, and assessment for learning through experimentation. The presented research-based proposals will be of interest to all who seek to improve physics teaching and learning.
This book presents research contributions focussing on the introduction of contemporary physics topics – mainly, but not exclusively, quantum physics – into high school currciula. Despite the important advances and discoveries in quantum physics and relativity which have revolutionized our views of nature and our everyday lives, the presence of these topics in high school physics education is still lacking. In this book physics education researchers report on the teaching and learning of quantum physics from different perspectives and discuss the design and use of different pedagogical approaches and educational pathways. There is still much debate as to what content is appropriate at high school level as well what pedagogical approaches and strategies should be adopted to support student learning. Currently there is a greater focus on how to teach modern physics at the high school level rather than classical physics. However, teachers still lack experience and availability of appropriate teaching and learning materials to support the coherent integration of Quantum Physics in high school curricula. All of the 19 papers presented in this book discuss innovative approaches for enhancing physics education in schools.
The Workshop Physics Activity Guide is a set of student workbooks designed to serve as the foundation for a two-semester calculus-based introductory physics course. It consists of four Modules, with a total of 28 units, that interweave text materials with activities that include prediction, qualitative observation, explanation, equation derivation, mathematical modeling, quantitative experiments, and problem solving. The modules help students understand the basis of knowledge in physics as interplay between observations, experiments, definitions, and mathematical theory. The inquiry-based activities in the modules give students the opportunity to work collaboratively to solve problems, while thinking critically to make predictions and observations. Students use a powerful set of computer tools to record, display, and analyze data, as well as to develop mathematical models of physical phenomena. The design of many of the activities is based on the outcomes of physics education research. Module 2 Unit 8 Momentum and Collisions in One Dimension Unit 9 Momentum and Collisions in Two Dimensions Unit 10 Work and Energy Unit 11 Energy Conservation Unit 12 Rotational Motion Unit 13 Rotational Momentum and its Relation to Torque Unit 14 Simple Harmonic Motion Unit 15 Oscillations, Determinism, and Chaos
"This is the third edition of the Activity Guide developed as part of the Workshop Physics Project. Although this Guide contains text material and experiments, it is neither a textbook nor a laboratory manual. It is a student workbook designed to serve as the foundation for a two-semester, calculus-based introductory physics course sequence that is student-centered and focuses on hands-on learning. The activities have been designed using the outcomes of physics education research and honed through years of classroom testing at Dickinson College. The Guide consists of 28 units that interweave written descriptions with activities that involve predictions, qualitative observations, explanations, equation derivations, mathematical modeling, quantitative experimentation, and problem solving. Throughout these units, students make use of a flexible set of computer-based data-acquisition tools to record, display, and analyze data, as well as to develop mathematical models of various physical phenomena"--