(Department of Electrical and Electronic Engineering)
Advanced Electromagnetic Waves
2005 Spring Semester (2-0-0)
Prof. Makoto ANDO and Assoc. Prof. Jiro HIROKAWA
Derivation and interpretation of Maxwell's equations, radiation from a dipole, direct integration of the
field equations, field equivalence theorem, boundary, edge and radiation conditions, Solutions for
homogeneous equations, canonical problems sloved by separation of variables and diffraction from
a half plane or a cylinder
2005 Spring Semester (2-0-0)
Prof. Kiyomichi ARAKI
Wireless Communication Systems; Wave propagation, reflection, refraction and diffraction;
Stochastic Behavior of wireless channel; Antenna and Diversity; Space and Time Signal Processing;
Modulation and Demodulation; Coding and Decoding; RF Devices and Circuit Design; Multiple
Access; Software defined radio ; MIMO Systems
2005 Spring Semester (2-0-0)
Prof. Tetsuya MIZUMOTO
Wave propagation in planar waveguides for microwave and optical integrated circuits and in optical
fibers. Coupled mode theory. Applications to microwave and lightwave circuits and devices, e.g.
coupled waveguides, multi/demultiplexers, and nonreciprocal devices.
2005 Autumn Semester (2-0-0)
Prof. Hirofumi AKAGI
Prerequisite: Circuit theory, and basic electric machine
Active power and reactive power, instantaneous power theory in three-phase circuits,
d-q transformation for ac motors machines, and vector control of ac motors.
2005 Spring Semester(2-0-0)
Prof. Akinori NISHIHARA
Prerequisite: Basic knowledge on signal processing, such as z-transform, Frourier analysis, sampling
theorem.
Realization of FIR and IIR systems and parasitic effects, robust digital filters, multirate signal
processing (sampling rate alteration), filter banks, wavelets, adaptive filters, digital signal processors,
etc.
(Department of Physical Electronics)
Electronic Materials A
2005 Spring Semester (2-0-0)
Prof. Masanori ABE and Assoc. Prof. Shigeki NAKAGAWA
Electronic properties of solids are lectured based on quantum mechanics. Beginning with
fundamentals of quantum mechanics, perturbation theory and an approximate method are given.
They will be applied to electromagnetic radiation in solids and chemical bonds based on molecular
orbital theory. Also, fundamentals of superconductivity are given, which are extended to
superconductivity devices. Exercises are carried out during the class to help understanding.
2005 Spring Semester (2-0-0)
Prof. Masanori ABE and Assoc. Prof. Yutaka MAJIMA
Fundamentals of crystallography, including lattice and point symmetry, are given to introduce
physical tensors (electric, magnetic, elastic optical, etc.) of crystals. Principles of crystal-structure
analyses and phonon vibrations are introduced, with which fundamentals of methodologies for
crystallographic analyses using X-ray, electron beams, scanning electron microscopes, etc. are given.
2004 Autumn Semester (2-0-0)
Prof. Mitsumasa IWAMOTO and Assoc. Prof. Shigeki NAKAGAWA
Fundamentals and advanced theories of magnetic properties and dielectric properties for the better
understanding of ferro- and ferri- magnetic materials and dielectric and ferroelectric materials.
Origins of magnetic moment, its alignment and anisotropy, electronic and optical properties in
advanced organic materials.
2004 Autumn Semester (2-0-0)
Prof. Shunri ODA
Operating speed in ULSI. Principles, current research status and future prospects of heterojunction
devices, quantum effect devices, single electron devices and superconducting devices.
2004 Autumn Semester (2-0-0)
Assoc. Prof. Hiroshi MIZUTA
Fundamentals of numerical simulation technologies for nanometer-scale electronic devices and
their applications to design and analysis of advanced devices. Semiconductor carrier transport
equation, drift-diffusion method, energy-balance equation method, Monte Carlo method,
numerical solution techniques for those semiconductor equations and quantum transport
simulation.
2005 Spring Semester (2-0-0)
Prof. Nobuo FUJII
Modeling of active devices using nullator-norator pairs, General analysis of networks containing
nullator-norator pairs, Stability of active networks, Advanced feedback theory, Analog filters, Active
RC filters, Switched Capacitor filters.
2005 Autumn Semester (2-0-0)
Prof. Akira MATSUZAWA
On the basis of Electronic Circuits and Device for undergraduate course, this course provides general
consideration on mixed signal systems and design and device technologies for mixed signal integrated
circuits. Current mixed signal systems; design technologies for high speed ADCs and DACs, sigma-delta
ADCs and DACs, PLL and DLL circuits, and CMOS RF circuits such as LNA, mixer, and VCO; and
device and EDA technologies will be covered.
2005 Spring Semester (2-0-0)
Prof. Akinori NISHIHARA
Prerequisite: Basic knowledge on signal processing, such as z-transform, Frourier analysis, sampling
theorem.
Realization of FIR and IIR systems and parasitic effects, robust digital filters, multirate signal
processing (sampling rate alteration), filter banks, wavelets, adaptive filters, digital signal processors,
etc.
2004 Autumn Semester (2-0-0)
Assoc. Prof. Adarsh SANDHU and John BANIECKI
This course is intended for nonnative speakers of English wishing to improve their ability
to (1) write a manuscript for a scientific journal; (2) give an oral presentation at an
international conference; and (3) prepare an effective poster presentation. Students will
be required to give oral presentations about their research projects, solve problems in
the physical sciences and engineering and to write a manuscript for submission to a
technical journal based on their graduate research projects.