Imatge de la portada

Enhancing Electromagnetics Instruction Using Matlab And Mathcad

Guardat en:
Publicat a:Association for Engineering Education - Engineering Library Division Papers (Jun 20, 2010), p. 15.509.1
Autor principal: Wentworth, Stuart
Altres autors: S. Hossein Mousavinezhad, Mani Mina, PAN, Wei
Publicat:
American Society for Engineering Education-ASEE
Matèries:
Computer algebra
Students
Mathematical analysis
Wireless communications
Applications programs
Engineering education
Matlab
Transmission lines
Medical imaging
Collision avoidance
Radio frequency identification
Airports
Coordinates
Colleges & universities
Cylindrical coordinates
Electrical engineering
Numerical analysis
Tools
Radar equipment
Transportation systems
Computer engineering
Magnetic resonance imaging
Antennas
Wave propagation
Electrostatics
Cartesian coordinates
Teaching
Engineering
Differentiation
Credit
Algebra
Understanding
Accés en línia:Citation/Abstract
Full text outside of ProQuest
Etiquetes: Afegir etiqueta
Sense etiquetes, Sigues el primer a etiquetar aquest registre!
Resum:MATLAB and MATHCAD can be very useful tools for use in electromagnetics courses. They can be used as demonstration tools to clarify important concepts, or for numerical analysis of problems that are difficult or impossible to solve analytically. MATLAB can serve as the students’ home laboratory, helping to develop their practical understanding of electromagnetics. MATHCAD, with its symbolic algebra system, is useful for analyzing complicated mathematical expressions and is ideal for subjects that deal with mathematical representations of real or complex functions. Examples show how these tools are used in undergraduate course from three universities. Electromagnetics in electrical engineering is generally taught as a one or a two semester sequence in the junior year. Also, some computer engineering students will take one semester of electromagnetics to get a better understanding of transmission lines and smart antennas. The trend has been to decrease coverage from the more traditional two semester sequence to a single semester course to make room for other topics. However, a de-emphasis is unfortunate since the subject is fundamental to the understanding of wireless communications, radar systems (such as new airport systems), GPS operation, transportation systems (anti-collision radar, maglev), RFID systems, medical imaging systems (MRI), and bioelectromagnetics. The universities involved in this paper have different approaches to covering Electromagnetics. One University presently has a two semester sequence of electromagnetics and presently uses the T-Lines first approach. The second university had a three (3) hour junior level course but increased it to four (4) starting in Fall of 2008. The extra credit may be just enough to cover more materials on transmission lines and some additional applications using software packages. The third university also requires a four (4) credit core electromagnetics course that begins with electrostatics and progresses through EM wave propagation and ends with transmission lines. Students can also take senior level classes in antennas, microwave engineering, high speed systems and optical systems. Electromagnetics can be challenging for students for several reasons. First, fields are vector quantities and students must visualize directions in space. This can be complicated by the necessity of studying different coordinate systems (Cartesian, cylindrical and spherical). Also, students are required to perform integration and differentiation, skills they have somewhat developed but have rarely applied. This paper will describe ways in which MATLAB and MATHCAD are employed in undergraduate electromagnetics courses at three universities.
Font:Library Science Database