EL3001 Engineering Electromagnetics I Kredit : Semester : Kode Kuliah KBK/Bidang Keahlian: Sifat: EL3001 3 SKS 5 Teknik Elektro Wajib Kuliah Sifat kuliah MK Dasar Engineering Kelompok Kuliah Course Title (Indonesian) Medan Elektromagnetik I Nama Matakuliah Engineering Electromagnetics I Course Title (English) Nama Matakuliah Vector analysis, line and area integral, electric-field and magnetic-field Short Description concepts, Maxwell's Law, flat wave, electromagnetics materials, bond limits, Silabus ringkas Poynting vector, static electromagnetics. The course explains the electromagnetics phenomenon and its basic laws, Goals analitically or by experiments Tujuan Instruksional Umum (TIU) Dept/PS: EL / EL, EC, EP, ET Fak: FTI ITB Offered To(PS Peserta) 1. MA2107 Matematika Teknik I Prerequisit Related Courses 2. MA2108 Matematika Teknik II Prerequisit 3. EL2003 Rangkaian Elektrik Prerequisit Knowledge = 76 % Facility/ x White board Percentage Skill = 9 % Media LCD/Infocus Attitude = 15 % Computer (lab) Course (kuliah) = 3 courseware Activity (hour/week) Tutorial (Responsi)= 1 e-learning Lab Works (Prakt)= 0 x Others. (OHP) Others = 0 UTS = 25 % Assessment/Penilaian UAS = 45 % Tugas = 5 % Others:…TEST 25 % 1. M. F. Iskander, Electromagnetics Fields & Waves, Prentice Hall Inc., 1992, References/Bibliography ISBN 0-13-249780-8. 2. S. V. Marshall and G.G. Skitek, Electromagnetic Concept & Applications, Prentice Hall Inc., 1990, ISBN 0-13-247842-0. 3. D.K. Cheng, Fundamentals of Engineering Electromagnetics, AddisonWesley, 1993, ISBN 0-201-56611-7. Pedagogy Strategy and Suggestions for Lecturers - Describe the course correlation with others disciplines in daily practice - Explain practical examples of electromagnetics facts/phenomenons - Give test every 2-3 week during the semester to supervise the progress of students' understanding level Course Descriptions Week # 1. Topics Sub Topics Goals Vectors Able to solve vector and vector field problems in cartesian, sylinder and sphere coordinate system. 2. Coulomb's Law 3. Coulomb's Law 4. Maxwell's Law in statics Vector algebra, cross and node multiplications, Cartesian coordinates, cylinder and coordinates transformations Electric fields, electric flux, Biot-Savart Laws, magnetic fields, magnetic flux, Lenz's Law The relation between electric and magnetic fields, line and area integral for scalar and vector, Maxwell's Law in integral form Vector difference, position vector, scalar gradient. 5. 6. TEST # 1 Maxwell's Law in statics Uniform flat-wave Vector difference, divergence theorems, pusaran vektor, Stokes theorem. Wave equation, electric and magnetic fields, Able to calculate the force in between small surfaces and calculate electric field of discrete charge and distributed charge. Understand the relation between electric and magnetic fields. Activity K/P/R/X/U K K K Understand static Maxwel's Law TEST # 1 Understand divergence theorem and U K pusaran pada vektor Understand electromagnetic wave equation and flat-wave parameters. K arah dan kecepatan rambat, TEST # 2 wave length, intrinsic impedance, wave polarisation, electromagnetic in material TEST # 2 7. Conductors Free electrons, mobility, conductivity; dielectric : polarization, polarization current, Ampere and Gauss Law in dielectric Understand the characteristics of conductors and ablet to calculate conductor and dielectric boundary conditions. 8. Semiconductors Electron and holes, mobility, conductivity, dopping, Lorenz law and force in electrical current Understand the characteristics of semiconductor material and able to calculate boundary condition between to dielectrics. 9. Midtest Magnetic Moment Magnetic materials: Understand magnetic U K K U K Week # Topics 10. Magnetic Moment 11. TEST # 3 Magnetic and Electric Energy 12. Static Electric TEST # 4 13. Moment Methods 14. Magnetization 15. TEST # 5 Review of all topics 16. TEST # 6 and 7 FINAL TEST Sub Topics Goals magnetisation, Maxwell law for random state materials. Electromagnetic field boundary, electrical and magnetic flux, polarisation and magnetisation Energy density, potential, power dissipation in conductors, Poynting theorem, electromagnetic wave in conductor, impedance, redaman Potential difference, potential gradien, electrical dipole, teori bayangan, capacitor, iteration technique, Laplace equation, Poisson equation. Exact solution for potential, magnetic circuit, magnetic circuit, magnetic vector potential, comparation to electrical fields. Ferromagnetic materials, inductance and coupled inductance. Activity K/P/R/X/U K TEST # 3 Able to calculate magnetic fields, and figure out electromagnetic power density. U K Able to calculate electric potential and understand the application of Laplace and Poisson Equation in electric field. K TEST # 4 U Able to determine potential using moment method. Understand the characteristic of magnetic materials K Short review / course summary TEST # 5 Review and understand the whole topics U R - TEST # 6 dan 7 FINAL TEST U U