**EE 340 ELECTROMAGNETIC THEORY**

Basics of Static electric and magnetic fields, Energy in fields, Maxwell’s equations, plane EM waves, Propagation in free space and in matter, Reflection and refraction, Guided EM waves, Transmission lines, Radiation of EM waves.**EE 416 OPTO-ELECTRONICS**

LEDs, semiconductor lasers, modulation of laser sources. Avalanche and PIN photodetectors and their characteristics. Solar cells. Optical fibers and their characteristics. Integrated optics. Fiber optic communication systems, system design consideration..**EE 441 MICROWAVES**

Active devices: LHTs, klystrons, magnetrons, TWTs, BWOs, microwave transistors; point contact, tunnel, PIN, and GUNN diodes; Parametric amplifier masers. Microwave circuits-theory of guiding systems, scattering matrix impedance transformation and matching. Passive devices: ferrites & ferrite devices, microwave cavity.**EE 442 ANTENNAS AND PROPAGATION**

Retarded potential, radiation from current element and dipole, radiation patterns, impedance, reciprocity. Various types of antennas, interferometers and multi-element arrays, Antenna Measurements. Ground wave propagation, terrain and earth curvature effects. Tropospheric propagation; fading, diffraction and scattering; Ionospheric Propagation-refractive index, critical frequencies, effects of magnetic field.**EE 443 RADAR SYSTEMS**

Radar equation, CW and Frequency Modulated Radars, MTI and pulse Doppler radar, MTI delay line cancellors. MTI from moving platform, Tracking radars. Mono-pulse tracking in range/Doppler; Electronic scanning radars, Beam forming and Steering methods, Noise and Clutter; Ambiguity function; Radar signal processing; SAR.**EE 444 RADIO ASTRONOMY**

Fundamentals of astronomy, Co-ordinate systems, Structure of the universe, Radio astronomy fundamentals, Electromagnetic wave propagation, Radio telescope Antennas, Reflector Antennas, Antenna arrays, Interferometry and aperture synthesis. Radio astronomy receivers, General principles, low noise amplifiers, digital auto-correlation receivers, Description of radio sources.

**EE 612 FIBER OPTIC SYSTEMS I**

Review of semiconductor physics - radiative recombination. LEDs, optical cavity, DH and other lasers. P-I-N and APD detectors, detector noise. Optical fibers - ray and mode theories, multimode and single-mode fibers, attenuation, dispersion. Gaussian beams. Power coupling, splices and connectors.**EE 640 COMPUTATIONAL ELECTRO-MAGNETICS**

Review of complex variables, conformal mappings, matrix calculus; Sturm Liouville equation; Eigenvalue problem; Guiding structures; Scattering media; Green’s function approach; Variational formulation, FEM, Generalized scattering matrix and planar circuit approach.**EE 641 ADVANCED ENGINEERING ELECTRO MAGNETICS**

Transmission line theory; Green’s function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction.**EE 642 ANTENNA ANALYSIS & SYNTHESIS**

Vector potential; antenna theorems and definitions; dipole, loop, slot radiators; aperture antennas; array theorems; pattern synthesis; self and mutual impedances; scanning antennas; signal processing antennas, travelling wave antennas; antenna measurements.**EE 643 SMART ANTENNAS FOR MOBILE COMMUNICATIONS**

Statistical signal processing concepts, Basics of mobile wireless communications. Radio-frequency signal modeling and channel characterization. Smart antennas and generalized array signal processing. Source localization problem. Joint angle and delay estimation. Smart antenna array configurations. Mobile communication systems with smart antennas.**EE 644 OE1 OPTICAL COMMUNICATION****EE 645 MONOLITHIC MICROWAVE ICS**

Scattering parameters of n-ports, Conductor and dielectric losses in planar transmission lines, coupled lines, multi-conductor lines, discontinuities, GaAs MESFET fabrication devices, High electron mobility transistor, Heterojunction bipolar transistor fabrication and modeling, NMIC technology and design.**EE 646 PHOTONIC NETWORKS AND SWITCHING**

Optical communications: Introduction to basic optical communications and devices. Optical multiplexing techniques - Wavelength division multiplexing, Optical frequency division multiplexing, time division multiplexing, code division multiplexing. Optical Networks: Conventional optical networks, SONET / SDH, FDDI, IEEE 802.3, DQDB, FCS, HIPPI etc. Multiple access optical networks, Topologies, Single channel networks, Multichannel networks, FTFR, FTTR, TTFR and TTTR, Single hop networks, Multihop networks, Multiaccess protocols for WDM networks, Switched optical networks. Optical amplification in all-optical networks. All-optical subscriber access networks. Design issues. Optical switching: Motivation, Spatial light modulator, Relational and non-relational switching devices, Fundamental limits on optical switching elements, Switching architectures, Free-space optical switching. Wavelength routed networks and other special topics. Soliton based networks, Optical networks management issues.**EE 647 MICROWAVE MEASUREMENTS AND DESIGN**

Experiments in basic microwave measurements; passive and active circuit characterization using network analyzer, spectrum analyzer and noise figure meter; PC based automated microwave measurements; integration of measurement and design of microwave circuits.**EE 648 MICROWAVE CIRCUITS**

Transmission lines for microwave circuits; waveguides, stripline, microstrip, slot line; microwave circuit design principles; passive circuits; impedance transformers, filters, hybrids, isolators etc., active circuits using semiconductor devices and tubes, detection and measurement of microwave signals.**EE 649 THE FINITE ELEMENT METHOD FOR ELECTRIC AND MAGNETIC FIELDS**

Introduction: Review of Electromagnetic Theory. Introduction to the Finite Element Method using electrostatic fields: Galerkin‘s method of weighted residuals, Minimum energy principle, Calculation of capacitance, electric field, electric forces from the potential solutions. Finite Element Concepts: Pre- processing, shape functions, isoparametric elements, meshing, solvers, post- processing. finite Element Modeling: Conductive media, steady currents; Magnetostatic fields, permanent Magnest, scalar and vector potentials; Electromagnetic fields. eddy current problems, modeling of moving parts; modeling of electrical circuits. Laboratory: Matlab and Femlab simulation**EE 673 DIGITAL COMMUNICATION NETWORKS**

OSI model, queueing theory, physical layer, error detection and correction, data link layer, ARQ strategies, framing, media access layer, modeling and analysis of important media access control protocols, FDDI and DQDB MAC protocols for LANs and MANs, network layer, flow control & routing, TCP/IP protocols, ATM.**EE 698E QUANTUM INFORMATICS**

#### Courses Offered to PG Students

**EE 641 ADVANCED ENGINEERING ELECTRO MAGNETICS**

Transmission line theory; Green’s function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction.**EE 645 MONOLITHIC MICROWAVE ICS**

Scattering parameters of n-ports, Conductor and dielectric losses in planar transmission lines, coupled lines, multi-conductor lines, discontinuities, GaAs MESFET fabrication devices, High electron mobility transistor, Heterojunction bipolar transistor fabrication and modeling, NMIC technology and design.**EE 646 PHOTONIC NETWORKS AND SWITCHING**

Optical communications: Introduction to basic optical communications and devices. Optical multiplexing techniques - Wavelength division multiplexing, Optical frequency division multiplexing, time division multiplexing, code division multiplexing. Optical Networks: Conventional optical networks, SONET / SDH, FDDI, IEEE 802.3, DQDB, FCS, HIPPI etc. Multiple access optical networks, Topologies, Single channel networks, Multichannel networks, FTFR, FTTR, TTFR and TTTR, Single hop networks, Multihop networks, Multiaccess protocols for WDM networks, Switched optical networks. Optical amplification in all-optical networks. All-optical subscriber access networks. Design issues. Optical switching: Motivation, Spatial light modulator, Relational and non-relational switching devices, Fundamental limits on optical switching elements, Switching architectures, Free-space optical switching. Wavelength routed networks and other special topics. Soliton based networks, Optical networks management issues.**EE 647 MICROWAVE MEASUREMENTS AND DESIGN**

Experiments in basic microwave measurements; passive and active circuit characterization using network analyzer, spectrum analyzer and noise figure meter; PC based automated microwave measurements; integration of measurement and design of microwave circuits.

**EE 642 ANTENNA ANALYSIS & SYNTHESIS**

Vector potential; antenna theorems and definitions; dipole, loop, slot radiators; aperture antennas; array theorems; pattern synthesis; self and mutual impedances; scanning antennas; signal processing antennas, travelling wave antennas; antenna measurements.**EE 648 MICROWAVE CIRCUITS**

Transmission lines for microwave circuits; waveguides, stripline, microstrip, slot line; microwave circuit design principles; passive circuits; impedance transformers, filters, hybrids, isolators etc., active circuits using semiconductor devices and tubes, detection and measurement of microwave signals.**EE 649 THE FINITE ELEMENT METHOD FOR ELECTRIC AND MAGNETIC FIELDS**

Introduction: Review of Electromagnetic Theory. Introduction to the Finite Element Method using electrostatic fields: Galerkin‘s method of weighted residuals, Minimum energy principle, Calculation of capacitance, electric field, electric forces from the potential solutions. Finite Element Concepts: Pre- processing, shape functions, isoparametric elements, meshing, solvers, post- processing. finite Element Modeling: Conductive media, steady currents; Magnetostatic fields, permanent Magnest, scalar and vector potentials; Electromagnetic fields. eddy current problems, modeling of moving parts; modeling of electrical circuits. Laboratory: Matlab and Femlab simulation.

**EE 641 ADVANCED ENGINEERING ELECTRO MAGNETICS**

Transmission line theory; Green’s function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction.**EE 645 MONOLITHIC MICROWAVE ICS**

Scattering parameters of n-ports, Conductor and dielectric losses in planar transmission lines, coupled lines, multi-conductor lines, discontinuities, GaAs MESFET fabrication devices, High electron mobility transistor, Heterojunction bipolar transistor fabrication and modeling, NMIC technology and design.**EE 647 MICROWAVE MEASUREMENTS AND DESIGN**

Experiments in basic microwave measurements; passive and active circuit characterization using network analyzer, spectrum analyzer and noise figure meter; PC based automated microwave measurements; integration of measurement and design of microwave circuits.

**EE 640 COMPUTATIONAL ELECTRO-MAGNETICS**

Review of complex variables, conformal mappings, matrix calculus; Sturm Liouville equation; Eigenvalue problem; Guiding structures; Scattering media; Green’s function approach; Variational formulation, FEM, Generalized scattering matrix and planar circuit approach.**EE 642 ANTENNA ANALYSIS & SYNTHESIS**

Vector potential; antenna theorems and definitions; dipole, loop, slot radiators; aperture antennas; array theorems; pattern synthesis; self and mutual impedances; scanning antennas; signal processing antennas, travelling wave antennas; antenna measurements.**EE 643 SMART ANTENNAS FOR MOBILE COMMUNICATIONS**

Statistical signal processing concepts, Basics of mobile wireless communications. Radio-frequency signal modeling and channel characterization. Smart antennas and generalized array signal processing. Source localization problem. Joint angle and delay estimation. Smart antenna array configurations. Mobile communication systems with smart antennas.**EE 646 PHOTONIC NETWORKS AND SWITCHING**

Optical communications: Introduction to basic optical communications and devices. Optical multiplexing techniques - Wavelength division multiplexing, Optical frequency division multiplexing, time division multiplexing, code division multiplexing. Optical Networks: Conventional optical networks, SONET / SDH, FDDI, IEEE 802.3, DQDB, FCS, HIPPI etc. Multiple access optical networks, Topologies, Single channel networks, Multichannel networks, FTFR, FTTR, TTFR and TTTR, Single hop networks, Multihop networks, Multiaccess protocols for WDM networks, Switched optical networks. Optical amplification in all-optical networks. All-optical subscriber access networks. Design issues. Optical switching: Motivation, Spatial light modulator, Relational and non-relational switching devices, Fundamental limits on optical switching elements, Switching architectures, Free-space optical switching. Wavelength routed networks and other special topics. Soliton based networks, Optical networks management issues.**EE 648 MICROWAVE CIRCUITS**

Transmission lines for microwave circuits; waveguides, stripline, microstrip, slot line; microwave circuit design principles; passive circuits; impedance transformers, filters, hybrids, isolators etc., active circuits using semiconductor devices and tubes, detection and measurement of microwave signals.**EE 649 THE FINITE ELEMENT METHOD FOR ELECTRIC AND MAGNETIC FIELDS**

Introduction: Review of Electromagnetic Theory. Introduction to the Finite Element Method using electrostatic fields: Galerkin‘s method of weighted residuals, Minimum energy principle, Calculation of capacitance, electric field, electric forces from the potential solutions. Finite Element Concepts: Pre- processing, shape functions, isoparametric elements, meshing, solvers, post- processing. finite Element Modeling: Conductive media, steady currents; Magnetostatic fields, permanent Magnest, scalar and vector potentials; Electromagnetic fields. eddy current problems, modeling of moving parts; modeling of electrical circuits. Laboratory: Matlab and Femlab simulation

**EE 641 ADVANCED ENGINEERING ELECTRO MAGNETICS**

Transmission line theory; Green’s function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction.**EE 645 MONOLITHIC MICROWAVE ICS**

Scattering parameters of n-ports, Conductor and dielectric losses in planar transmission lines, coupled lines, multi-conductor lines, discontinuities, GaAs MESFET fabrication devices, High electron mobility transistor, Heterojunction bipolar transistor fabrication and modeling, NMIC technology and design.**EE 647 MICROWAVE MEASUREMENTS AND DESIGN**

Experiments in basic microwave measurements; passive and active circuit characterization using network analyzer, spectrum analyzer and noise figure meter; PC based automated microwave measurements; integration of measurement and design of microwave circuits.

**EE 642 ANTENNA ANALYSIS & SYNTHESIS**

Vector potential; antenna theorems and definitions; dipole, loop, slot radiators; aperture antennas; array theorems; pattern synthesis; self and mutual impedances; scanning antennas; signal processing antennas, travelling wave antennas; antenna measurements.**EE 643 SMART ANTENNAS FOR MOBILE COMMUNICATIONS**

Statistical signal processing concepts, Basics of mobile wireless communications. Radio-frequency signal modeling and channel characterization. Smart antennas and generalized array signal processing. Source localization problem. Joint angle and delay estimation. Smart antenna array configurations. Mobile communication systems with smart antennas.**EE 646 PHOTONIC NETWORKS AND SWITCHING**

Optical communications: Introduction to basic optical communications and devices. Optical multiplexing techniques - Wavelength division multiplexing, Optical frequency division multiplexing, time division multiplexing, code division multiplexing. Optical Networks: Conventional optical networks, SONET / SDH, FDDI, IEEE 802.3, DQDB, FCS, HIPPI etc. Multiple access optical networks, Topologies, Single channel networks, Multichannel networks, FTFR, FTTR, TTFR and TTTR, Single hop networks, Multihop networks, Multiaccess protocols for WDM networks, Switched optical networks. Optical amplification in all-optical networks. All-optical subscriber access networks. Design issues. Optical switching: Motivation, Spatial light modulator, Relational and non-relational switching devices, Fundamental limits on optical switching elements, Switching architectures, Free-space optical switching. Wavelength routed networks and other special topics. Soliton based networks, Optical networks management issues.**EE 648 MICROWAVE CIRCUITS**

Transmission lines for microwave circuits; waveguides, stripline, microstrip, slot line; microwave circuit design principles; passive circuits; impedance transformers, filters, hybrids, isolators etc., active circuits using semiconductor devices and tubes, detection and measurement of microwave signals.**EE 649 THE FINITE ELEMENT METHOD FOR ELECTRIC AND MAGNETIC FIELDS**

Introduction: Review of Electromagnetic Theory. Introduction to the Finite Element Method using electrostatic fields: Galerkin‘s method of weighted residuals, Minimum energy principle, Calculation of capacitance, electric field, electric forces from the potential solutions. Finite Element Concepts: Pre- processing, shape functions, isoparametric elements, meshing, solvers, post- processing. finite Element Modeling: Conductive media, steady currents; Magnetostatic fields, permanent Magnest, scalar and vector potentials; Electromagnetic fields. eddy current problems, modeling of moving parts; modeling of electrical circuits. Laboratory: Matlab and Femlab simulation

**EE 612 FIBER OPTIC SYSTEMS I**

Review of semiconductor physics - radiative recombination. LEDs, optical cavity, DH and other lasers. P-I-N and APD detectors, detector noise. Optical fibers - ray and mode theories, multimode and single-mode fibers, attenuation, dispersion. Gaussian beams. Power coupling, splices and connectors.**EE 641 ADVANCED ENGINEERING ELECTRO MAGNETICS**

Transmission line theory; Green’s function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction.**EE 644 OE1 OPTICAL COMMUNICATION****EE 647 MICROWAVE MEASUREMENTS AND DESIGN**

Experiments in basic microwave measurements; passive and active circuit characterization using network analyzer, spectrum analyzer and noise figure meter; PC based automated microwave measurements; integration of measurement and design of microwave circuits.**EE 673 DIGITAL COMMUNICATION NETWORKS**

OSI model, queueing theory, physical layer, error detection and correction, data link layer, ARQ strategies, framing, media access layer, modeling and analysis of important media access control protocols, FDDI and DQDB MAC protocols for LANs and MANs, network layer, flow control & routing, TCP/IP protocols, ATM.**EE 698E QUANTUM INFORMATICS**

**EE 642 ANTENNA ANALYSIS & SYNTHESIS**

Vector potential; antenna theorems and definitions; dipole, loop, slot radiators; aperture antennas; array theorems; pattern synthesis; self and mutual impedances; scanning antennas; signal processing antennas, travelling wave antennas; antenna measurements.**EE 640 COMPUTATIONAL ELECTRO-MAGNETICS**

Review of complex variables, conformal mappings, matrix calculus; Sturm Liouville equation; Eigenvalue problem; Guiding structures; Scattering media; Green’s function approach; Variational formulation, FEM, Generalized scattering matrix and planar circuit approach.**EE 648 MICROWAVE CIRCUITS**

Transmission lines for microwave circuits; waveguides, stripline, microstrip, slot line; microwave circuit design principles; passive circuits; impedance transformers, filters, hybrids, isolators etc., active circuits using semiconductor devices and tubes, detection and measurement of microwave signals.**EE 649 THE FINITE ELEMENT METHOD FOR ELECTRIC AND MAGNETIC FIELDS**

Introduction: Review of Electromagnetic Theory. Introduction to the Finite Element Method using electrostatic fields: Galerkin‘s method of weighted residuals, Minimum energy principle, Calculation of capacitance, electric field, electric forces from the potential solutions. Finite Element Concepts: Pre- processing, shape functions, isoparametric elements, meshing, solvers, post- processing. finite Element Modeling: Conductive media, steady currents; Magnetostatic fields, permanent Magnest, scalar and vector potentials; Electromagnetic fields. eddy current problems, modeling of moving parts; modeling of electrical circuits. Laboratory: Matlab and Femlab simulation**EE686 MICROWAVE IMAGING AND NONDESTRUCTIVE TESTING****EE698X ADVANCED MOSFET MODELING**

**EE 612 FIBER OPTIC SYSTEMS I**

Review of semiconductor physics - radiative recombination. LEDs, optical cavity, DH and other lasers. P-I-N and APD detectors, detector noise. Optical fibers - ray and mode theories, multimode and single-mode fibers, attenuation, dispersion. Gaussian beams. Power coupling, splices and connectors.**EE 641 ADVANCED ENGINEERING ELECTRO MAGNETICS**

Transmission line theory; Green’s function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction.**EE 647 MICROWAVE MEASUREMENTS AND DESIGN**

Experiments in basic microwave measurements; passive and active circuit characterization using network analyzer, spectrum analyzer and noise figure meter; PC based automated microwave measurements; integration of measurement and design of microwave circuits.**EE 645 MONOLITHIC MICROWAVE ICS**

Scattering parameters of n-ports, Conductor and dielectric losses in planar transmission lines, coupled lines, multi-conductor lines, discontinuities, GaAs MESFET fabrication devices, High electron mobility transistor, Heterojunction bipolar transistor fabrication and modeling, NMIC technology and design.**EE 646 PHOTONIC NETWORKS AND SWITCHING**

Optical communications: Introduction to basic optical communications and devices. Optical multiplexing techniques - Wavelength division multiplexing, Optical frequency division multiplexing, time division multiplexing, code division multiplexing. Optical Networks: Conventional optical networks, SONET / SDH, FDDI, IEEE 802.3, DQDB, FCS, HIPPI etc. Multiple access optical networks, Topologies, Single channel networks, Multichannel networks, FTFR, FTTR, TTFR and TTTR, Single hop networks, Multihop networks, Multiaccess protocols for WDM networks, Switched optical networks. Optical amplification in all-optical networks. All-optical subscriber access networks. Design issues. Optical switching: Motivation, Spatial light modulator, Relational and non-relational switching devices, Fundamental limits on optical switching elements, Switching architectures, Free-space optical switching. Wavelength routed networks and other special topics. Soliton based networks, Optical networks management issues.**EE 698E QUANTUM INFORMATICS**

**EE 642 ANTENNA ANALYSIS & SYNTHESIS**

Vector potential; antenna theorems and definitions; dipole, loop, slot radiators; aperture antennas; array theorems; pattern synthesis; self and mutual impedances; scanning antennas; signal processing antennas, travelling wave antennas; antenna measurements.**EE 640 COMPUTATIONAL ELECTRO-MAGNETICS**

Review of complex variables, conformal mappings, matrix calculus; Sturm Liouville equation; Eigenvalue problem; Guiding structures; Scattering media; Green’s function approach; Variational formulation, FEM, Generalized scattering matrix and planar circuit approach.**EE 648 MICROWAVE CIRCUITS**

Transmission lines for microwave circuits; waveguides, stripline, microstrip, slot line; microwave circuit design principles; passive circuits; impedance transformers, filters, hybrids, isolators etc., active circuits using semiconductor devices and tubes, detection and measurement of microwave signals.**EE 649 THE FINITE ELEMENT METHOD FOR ELECTRIC AND MAGNETIC FIELDS**

Introduction: Review of Electromagnetic Theory. Introduction to the Finite Element Method using electrostatic fields: Galerkin‘s method of weighted residuals, Minimum energy principle, Calculation of capacitance, electric field, electric forces from the potential solutions. Finite Element Concepts: Pre- processing, shape functions, isoparametric elements, meshing, solvers, post- processing. finite Element Modeling: Conductive media, steady currents; Magnetostatic fields, permanent Magnest, scalar and vector potentials; Electromagnetic fields. eddy current problems, modeling of moving parts; modeling of electrical circuits. Laboratory: Matlab and Femlab simulation**EE686 MICROWAVE IMAGING, CHARACTERIZATION AND NONDESTRUCTIVE TESTING**

**EE 612 FIBER OPTIC SYSTEMS I**

Review of semiconductor physics - radiative recombination. LEDs, optical cavity, DH and other lasers. P-I-N and APD detectors, detector noise. Optical fibers - ray and mode theories, multimode and single-mode fibers, attenuation, dispersion. Gaussian beams. Power coupling, splices and connectors.**EE 641 ADVANCED ENGINEERING ELECTRO MAGNETICS**

Transmission line theory; Green’s function and integral transform techniques; Wave propagation and polarization parameters; reflection and transmission across an interface; waveguides, cavity resonators, scattering by cylinders, wedges, spheres etc. Geometric theory of diffraction.**EE 647 MICROWAVE MEASUREMENTS AND DESIGN**

Experiments in basic microwave measurements; passive and active circuit characterization using network analyzer, spectrum analyzer and noise figure meter; PC based automated microwave measurements; integration of measurement and design of microwave circuits.**EE 645 MONOLITHIC MICROWAVE ICS**

Scattering parameters of n-ports, Conductor and dielectric losses in planar transmission lines, coupled lines, multi-conductor lines, discontinuities, GaAs MESFET fabrication devices, High electron mobility transistor, Heterojunction bipolar transistor fabrication and modeling, NMIC technology and design.**EE 646 PHOTONIC NETWORKS AND SWITCHING**

Optical communications: Introduction to basic optical communications and devices. Optical multiplexing techniques - Wavelength division multiplexing, Optical frequency division multiplexing, time division multiplexing, code division multiplexing. Optical Networks: Conventional optical networks, SONET / SDH, FDDI, IEEE 802.3, DQDB, FCS, HIPPI etc. Multiple access optical networks, Topologies, Single channel networks, Multichannel networks, FTFR, FTTR, TTFR and TTTR, Single hop networks, Multihop networks, Multiaccess protocols for WDM networks, Switched optical networks. Optical amplification in all-optical networks. All-optical subscriber access networks. Design issues. Optical switching: Motivation, Spatial light modulator, Relational and non-relational switching devices, Fundamental limits on optical switching elements, Switching architectures, Free-space optical switching. Wavelength routed networks and other special topics. Soliton based networks, Optical networks management issues.**EE 698E QUANTUM INFORMATICS**

**EE 642 ANTENNA ANALYSIS & SYNTHESIS**

Vector potential; antenna theorems and definitions; dipole, loop, slot radiators; aperture antennas; array theorems; pattern synthesis; self and mutual impedances; scanning antennas; signal processing antennas, travelling wave antennas; antenna measurements.**EE 640 COMPUTATIONAL ELECTRO-MAGNETICS**

Review of complex variables, conformal mappings, matrix calculus; Sturm Liouville equation; Eigenvalue problem; Guiding structures; Scattering media; Green’s function approach; Variational formulation, FEM, Generalized scattering matrix and planar circuit approach.**EE 648 MICROWAVE CIRCUITS**

Transmission lines for microwave circuits; waveguides, stripline, microstrip, slot line; microwave circuit design principles; passive circuits; impedance transformers, filters, hybrids, isolators etc., active circuits using semiconductor devices and tubes, detection and measurement of microwave signals.**EE 649 THE FINITE ELEMENT METHOD FOR ELECTRIC AND MAGNETIC FIELDS**

Introduction: Review of Electromagnetic Theory. Introduction to the Finite Element Method using electrostatic fields: Galerkin‘s method of weighted residuals, Minimum energy principle, Calculation of capacitance, electric field, electric forces from the potential solutions. Finite Element Concepts: Pre- processing, shape functions, isoparametric elements, meshing, solvers, post- processing. finite Element Modeling: Conductive media, steady currents; Magnetostatic fields, permanent Magnest, scalar and vector potentials; Electromagnetic fields. eddy current problems, modeling of moving parts; modeling of electrical circuits. Laboratory: Matlab and Femlab simulation