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The University of Jordan School of Faculty of Engineering Department of Electrical Engineering 1st Semester – A.Y. 2014/2015 Course: Instructor: Course Website: Catalog Data: Electromagnetics I – 0903251 (3 Cr. – Core Course) Dr. Mohamed K Abdelazeez Office: E317, Telephone: 5355000 ext 22837, Email: [email protected] Dr. Loay Khalaf Office: E200-5, Telephone: 5355000 ext 22869, Email: [email protected] Office Hours: will be posted soon Introduction. Vectors and vector operations. Coordinate systems. Coulomb’s law and electric field. Potential and gradient. Electric flux density. Gauss law and divergence theorem. Electric fields in material space. Capacitors. Boundary conditions, Poisson’s and Laplace’s equations. Method of images. Biot-Savart’s law. Ampere’s law. The curl and Stock’s theorem. Magnetic force, torque and moment. Magnetic vector potential. Practical applications. Magnetic properties of materials. The B-H curve. Boundary conditions. Inductors. Magnetic circuits. Interaction between fields and charged particles. Faraday’s law. Displacement current. Maxwell’s equations. Continuity equation and the relaxation relationship. Time-harmonic fields and the hysteresis concept. Prerequisites by Course: 0302102– General Physics II. Prerequisites By Topic: Students are assumed to have a background in the following topics: Differentiation and Integration and vector calculus. Basic electricity and magnetism Textbook: M. N., O. Sadiku, Elements of Electromagnetics, 4 th Ed., Oxford University Press, 2005. References: Electromagnetics, J. D. Kraus, 4th Ed., McGraw-Hill, 1992. Engineering Electromagnetics, W. H. Hayt, Jr. andJ.A. Buck, 6 th Ed., McGraw- Hill Book Co.,2007. Electromagnetic Concepts & Applications, S. V. Marshall, and G. G. Skitek, 2nd Ed., Prentice-Hall, 1987. Basic Electromagnetic Fields, H. P. Neff, Jr., Harper & Row,1981 Introduction to Electromagnetic Fields, C. R. Paul, K. W. Whites and S. A. Nasar, 3rd Ed., McGraw-Hill, 1998. Schedule & Duration: Minimum Student Material: Minimum College Facilities: 16 Weeks, 42 contact hours (50 minutes each) including exams. Course Objectives: The overall objective of this course is to provide the student with the knowledge and proficiency to analyse electrostatic sources and the resulting electric fields, magnetostatic sources and the resulting mgetic fields. In addition the student is introduced to the concepts of electric and magnetic characteristics of materials. Textbook, class handouts, scientific calculator, and an access to a personal computer. Classroom with blackboard (projection display facilities will be useful), library, and computational facilities. Course Learning Outcomes and Relation to ABET Student Outcomes: Upon successful completion of this course, a student should: 1. Utilize the different coordinate systems in solving physical problems 2. Identify the relations between electrostatic sources and fields 3. Understand the gradient and divergence concepts, electrical polarization of material 4. Identify the relation between magneto-static sources and fields 5. Understand the Curl concept, magnetic polarization of the magnetic materials and the concept of the magnetic circuits 6. Characterize the interaction between charged particles and electric and magnetic fields. 7. Grasp the concepts of time varying fields and the implication of these concepts for future courses and applications [a] [a, e] [a, e] [a, e] [a, e] [a,c, e] [a,c, e] Course Topics: 1. Topic Description Vector Analysis : Vector operations, Coordinate systems (cartesian, cylindrical and spherical): components, unit vectors, infinitismal length, area and volume, dot and cross products, conversion from one system to another. Hrs 6 2. Electrostatic sources and fields: Point charge, line, surface and volume charge densitis, Coulomb's law and electric field intensity, potential and gradient. Electric flux density, Gauss law and the divergence theorem 10 3. Electric fields in material space and boundary value problems: Electric dipole, electric polarization, capacitors and boundary conditions. Poisson's and Laplace's equations. The method of images. Magnetic sources and fields: Line current, linear and surface current densities, Biot-Savart's law, Ampere's law, the curl and the Stock's theorem. Magnetic force, torque, moment and the magnetic vector potential Magnetic fields in material space and boundary value problems: Magnetic dipole, Magnetic Properties of materials, B-H curve. Boundary conditions, inductors and the magnetic circuits Time varying fields: Faraday's law, displacement current and Maxwell's equations. Continuity equation and the relaxation relationship. Time-harmonic fields and the hysteresis concept, magnetic vector potential and retarded fields. 8 4. 5. 6. 8 8 8 Ground Rules: Attendance is required and highly encouraged. To that end, attendance will be taken every lecture. All exams (including the final exam) should be considered cumulative. Exams are closed book. No scratch paper is allowed. You will be held responsible for all reading material assigned, even if it is not explicitly covered in lecture notes. Assessments: Grading policy: Exams. First Exam Midterm Exam Final Exam Total Last Updated: September 2014 20 % 30 % 50 % 100%