iBerry

exposure to the types of problems that electrical and computer engineers are asked to solve: Complex Numbers, functions e^x and e^jΘ, Phasors, Linear Algebra, Vector Graphics, Filtering, Binary Codes, Introduction to MATLAB, Edix Editor, Useful Mathematical Identities

Introduction, Digital Logic, Boolean Algebra, Minimization hazard cover in K-Maps, Combinational circuit design, adders, subtractors, complex circuits, Combinational Design with PLAs, synchronous sequential circuits,design of sequential modules,registers and counters, FSM, optimizations, PLDs, arithmetic circuits, algorithmic state machines
 

concept of sound and be introduced to the physics behind travelling pressure waves as the physical manifestation of sound. You will also learn about the subjective perception of pitch and loudness, in particular their relationship to frequency and amplitude.

MOSFET and CMOS, heterojunction BJT, photonic devices, non-ideal characteristics of MOSFETs (channel-length modulation and short-channel effects), threshold voltage modification by varying the dopant concentration, MOS scaling, CMOS inverter, transfer characteristics related to the CMOS design
 

Geometrical optics, Mechanical and electromagnetic oscillations, Basic properties of waves, Mechanical waves, Electromagnetic waves

basic concepts of electromagnetism, lightning, pacemakers, electric shock treatment, electrocardiograms, metal detectors, musical instruments, magnetic levitation, bullet trains, electric motors, radios, TV, Car coils, superconductivity, aurora borealis, rainbows, radio telescopes, interferometers, particle accelerators, mass spectrometers, red sunsets, blue skies, haloes around sun & moon, color perception, Doppler effect, big-bang cosmology
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emphasis on basics and applications to Nuclear Science and Engineering: electrostatics, magnetostatics, electromagnetic radiation, applications include transmission lines, waveguides, antennas, scattering, shielding, charged particle collisions, Bremsstrahlung radiation, Cerenkov radiation

photons, electrons, phonons, and molecules as energy carriers, fundamental understanding and descriptive tools for energy and heat transport processes from nanoscale continuously to macroscale: energy levels, statistical behavior and internal energy, energy transport, scattering, heat generation processes, Boltzmann equation, derivation of classical laws, deviation from classical laws at nanoscale, applications in nano- and microtechnology.