ChabotCollege

Course Outline for Physics 4C, page 1

Fall 2005

ChabotCollegeFall 2005

Replaced Fall 2010

Course Outline for Physics 4C

GENERAL PHYSICS III

Catalog Description:

4C - General Physics III 5 units

Electromagnetic waves, electromagnetic spectrum including reflection, refraction, diffraction, interference, polarization, fluids, sound waves and thermodynamics. Prerequisite: Physics 4B and Mathematics 3 (both completed with grade of C or higher). 4 hours lecture, 3 hours laboratory.

[Typical contact hours: lecture 70, laboratory 52.5]

Prerequisite Skills:

Before entering the course the student should be able to:

1.analyze and solve a variety of problems often using calculus in topics such as:

a.mechanical waves;

b.electrostatics;

c.electric potential and potential energy;

d.electric currents and DC circuits;

e.magnetism;

f.electromagnetic induction;

g.alternating circuits;

2.operate standard laboratory equipment;

3.analyze laboratory data;

4.write comprehensive laboratory reports;

5.transform points and equations among rectangular, cylindrical, and spherical coordinates and sketch their graphs as well as quadric surfaces;

6.parametrize curves using vector functions of one variable and analyze them (e.g. find unit tangent, unit normal, curvature);

7.sketch the graphs of functions of two variables using level curves, traces in coordinate planes, symmetry, etc;

8.extend the concepts of limits, continuity, differentiability and differential of single variable functions to functions of two variables;

9.compute limits, partial derivatives, total differential, gradient, directional derivatives and interpret them geometrically and in terms of rate of change;

10.apply partial derivatives and/or gradients to problems involving tangent planes and linear approximation, and optimization, especially using Lagrange multipliers;

11.compute double and triple integrals directly or using change of variables and explain the geometric interpretation of Jacobians;

12.apply differential operators gradient, divergence, curl and Laplacian to scalar and vector field and interpret the results;

13.compute line integrals using parametrizations for curves;

14.parametrize surfaces using vector functions of two variables, and compute their areas;

15.compute surface integrals of scalar functions and vector functions using parametrization for surfaces;

16.interpret the theorems of Green, Stokes and Gauss physically as well as mathematically (as the generalizations of the Fundamental Theorem of Calculus), and use them to compute line and surface integrals;

17.find scalar potentials for conservative vector field.

Expected Outcomes for Students:

Upon completion of the course, the student should be able to:

1.analyze and solve a variety of problems often using calculus in topics such as:

a.electromagnetic wave phenomena;

b.optics;

c.fluids;

d.sound waves;

e.thermodynamics;

2.operate standard laboratory equipment;

3.analyze laboratory data;

4.write comprehensive laboratory reports.

Course Content:

1.Light and radio waves

2.Reflection and refraction

3.Interference

4.Diffraction

5.Polarization

6.Fluids

7.Sound waves

8.Temperature

9.Thermal expansion and conduction

10.Kinetic theory

11.Ideal gases

12.Laws of thermodynamics

Methods of Presentation:

1.Lecture and discussion.

2.Problem solving.

3.Demonstrations.

4.Laboratory experimentation.

Assignments and Methods of Evaluating Student Progress:

1.Typical Assignments

a.Weekly homework/question sets

b.Laboratory reports (individual and group), including computer-based data acquisition and analysis

c.Special exercise worksheets, problem review, and computer simulations and tutorials; both individuals and group activities and research papers

d.Participation in email and web-based instruction, discussion and tutorials. Internet research on topics dealing with physics and its applications to technology

2.Methods of Evaluating Student Progress

a.Quizzes

b.Midterm examinations

c.Final examination

d.Laboratory reports

Textbook(s) (Typical):

University Physics with Modern Physics, Young and Freedman, Pearson/Addison Wesley , 2004

Special Student Materials:

None.

NA:al

Revised: 10/2005