Tutorials In Introductory Physics and Homework Package by Lillian C. McDermottTutorials In Introductory Physics and Homework Package by Lillian C. McDermott

Tutorials In Introductory Physics and Homework Package

byLillian C. McDermott, Peter S. Shaffer, Physics Education Group

Book & Toy | August 20, 2001

not yet rated|write a review

Pricing and Purchase Info

$64.90

Earn 325 plum® points

Out of stock online

Not available in stores

about

This landmark book presents a series of physics tutorials designed by a leading physics education research group. Emphasizing the development of concepts and scientific reasoning skills, the tutorials focus on common conceptual and reasoning difficulties. The tutorials cover a range of topics in Mechanics, E & M, and Waves & Optics.

Details & Specs

Title:Tutorials In Introductory Physics and Homework PackageFormat:Book & ToyDimensions:445 pages, 10.7 × 8.3 × 0.9 inPublished:August 20, 2001Publisher:Pearson EducationLanguage:English

The following ISBNs are associated with this title:

ISBN - 10:0130970697

ISBN - 13:9780130970695

Look for similar items by category:

Customer Reviews of Tutorials In Introductory Physics and Homework Package

Reviews

Extra Content

From the Author

Tutorials in Introductory Physics is a set of instructional materials intended to supplement the lectures and textbook of a standard introductory physics course. The emphasis in the tutorials is on the development of important physical concepts and scientific reasoning skills, not on solving the standard quantitative problems found in traditional textbooks. There is increasing evidence that after instruction in a typical course, many students are unable to apply the physics formalism that they have studied to situations that they have not expressly memorized. In order for meaningful learning to occur, students need more assistance than they can obtain through listening to lectures, reading the textbook, and solving standard quantitative problems. It can be difficult for students who are studying physics for the first time to recognize what they do and do not understand and to learn to ask themselves the types of questions necessary to come to a functional understanding of the material. Tutorials in Introductory Physics provides a structure that promotes the active mental engagement of students in the process of learning physics. Questions in the tutorials guide students through the reasoning necessary to construct concepts and to apply them in realworld situations. The tutorials also provide practice in interpreting various representations (e.g., verbal descriptions, diagrams, graphs, and formulas) and in translating back and forth between them. For the most part, the tutorials are intended to be used after concepts have been introduced in the lectures and the laboratory, although most can serve to introduce the topic as well. The tutorials comprise an integrated system of pretests, worksheets, homework assignments, and posttests. The tutorial sequence begins with a pretest. These are usually on material already presented in lecture or textbook but not yet covered in tutorial. The pretests help students identify what they do and not understand about the material and what they are expected to learn in the upcoming tutorial. They also inform the instructors about the level of student understanding. The worksheets, which consist of carefully sequenced tasks and questions, provide the structure for the tutorial sessions. Students work together in small groups, constructing answers for themselves through discussions with one another and with the tutorial instructors. The tutorial instructors do not lecture but ask questions designed to help students find their own answers. The tutorial homework reinforces and extends what is covered in the worksheets. For the tutorials to be most effective, it is important that course examinations include questions that emphasize the concepts and reasoning skills developed in the tutorials. The tutorials are primarily designed for a small class setting but have proved to be adaptable to other instructional environments. The curriculum has been shown to be effective for students in regular and honors sections of calculusbased and algebrabased physics. The tutorials have been developed through an iterative cycle of: research on the learning and teaching of physics, design of curriculum based on this research, and assessment through rigorous pretesting and posttesting in the classroom. Tutorials in Introductory Physics has been developed and tested at the University of Washington and pilottested at other colleges and universities. Comments on the First Edition Ongoing research has led to modifications to the tutorials and associated homework in the Preliminary Edition of Tutorials in Introductory Physics. The First Edition incorporates these changes and also includes several new tutorials on topics covered in the Preliminary Edition. In addition, the First Edition contains a new section with tutorials on topics in hydrostatics, thermal physics, and modern physics.

Read from the Book

Tutorials in Introductory Physics is a set of instructional materials intended to supplement the lectures and textbook of a standard introductory physics course. The emphasis in the tutorials is on the development of important physical concepts and scientific reasoning skills, not on solving the standard quantitative problems found in traditional textbooks. There is increasing evidence that after instruction in a typical course, many students are unable to apply the physics formalism that they have studied to situations that they have not expressly memorized. In order for meaningful learning to occur, students need more assistance than they can obtain through listening to lectures, reading the textbook, and solving standard quantitative problems. It can be difficult for students who are studying physics for the first time to recognize what they do and do not understand and to learn to ask themselves the types of questions necessary to come to a functional understanding of the material. Tutorials in Introductory Physics provides a structure that promotes the active mental engagement of students in the process of learning physics. Questions in the tutorials guide students through the reasoning necessary to construct concepts and to apply them in real-world situations. The tutorials also provide practice in interpreting various representations (e.g., verbal descriptions, diagrams, graphs, and formulas) and in translating back and forth between them. For the most part, the tutorials are intended to be used after concepts have been introduced in the lectures and the laboratory, although most can serve to introduce the topic as well. The tutorials comprise an integrated system of pretests, worksheets, homework assignments, and post-tests. The tutorial sequence begins with a pretest. These are usually on material already presented in lecture or textbook but not yet covered in tutorial. The pretests help students identify what they do and not understand about the material and what they are expected to learn in the upcoming tutorial. They also inform the instructors about the level of student understanding. The worksheets, which consist of carefully sequenced tasks and questions, provide the structure for the tutorial sessions. Students work together in small groups, constructing answers for themselves through discussions with one another and with the tutorial instructors. The tutorial instructors do not lecture but ask questions designed to help students find their own answers. The tutorial homework reinforces and extends what is covered in the worksheets. For the tutorials to be most effective, it is important that course examinations include questions that emphasize the concepts and reasoning skills developed in the tutorials. The tutorials are primarily designed for a small class setting but have proved to be adaptable to other instructional environments. The curriculum has been shown to be effective for students in regular and honors sections of calculus-based and algebra-based physics. The tutorials have been developed through an iterative cycle of: research on the learning and teaching of physics, design of curriculum based on this research, and assessment through rigorous pretesting and post-testing in the classroom. Tutorials in Introductory Physics has been developed and tested at the University of Washington and pilot-tested at other colleges and universities. Comments on the First Edition Ongoing research has led to modifications to the tutorials and associated homework in the Preliminary Edition of Tutorials in Introductory Physics. The First Edition incorporates these changes and also includes several new tutorials on topics covered in the Preliminary Edition. In addition, the First Edition contains a new section with tutorials on topics in hydrostatics, thermal physics, and modern physics.

Table of Contents

I. MECHANICS.

Kinematics.

Velocity. Representations of Motion. Acceleration in One Dimension. Motion in Two Dimensions. Relative Motion.

Newton's Law.

Forces. Newton's Second and Third Laws. Tension.

Energy and Momentum.

Work and the Work-Energy Theorem. Changes in Energy and Momentum. Conservation of Momentum in One Dimension. Conservation of Momentum in Two Dimensions.

Rotation.

Rotational Motion. Dynamics of Rigid Bodies. Equilibrium of Rigid Bodies.

II. ELECTRICITY AND MAGNETISM.

Electrostatics.

Charge. Electric Field and Flux. Gauss' Law. Electric Potential Difference. Capacitance.

Electric Circuits.

A Model for Circuits Part 1: Current and Resistance. A Model for Circuits Part 2: Potential Difference. RC Circuits.

Magnetism.

Magnets and Magnetic Fields. Magnetic Interactions.

Electromagnetism.

Lenz' Law. Faraday's Law and Applications.

III. WAVES.

Waves.

Superposition and Reflection of Pulses. Reflection and Transmission. Propagation and Refraction of Periodic Waves. Electromagnetic Waves.

IV. OPTICS.

Geometrical Optics.

Light and Shadow. Plane Mirrors. Curved Mirrors and Multiple Reflections. Interpretation of Ray Diagrams. Convex Lenses. Magnification.

Physical Optics.

Two-Source Interference. Wave Properties of Light. Multiple-Slit Interference. A Model for Single-Slit Diffraction. Combined Interference and Diffraction. Thin-Filmed Interference. Polarization.

V. SELECTED TOPICS.

Hydrostatics.

Pressure in a Liquid. Buoyancy.

Thermodynamics.

Ideal Gas Law. First Law of Thermodynamics.

Modern Physics.

Wave Properties of Matter. Photoelectric Effect.