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Vous consultez la version 2019-2020 du catalogue. GÉNIE ÉLECTRIQUE (ELG) ELG 21

Vous consultez la version 2019-2020 du catalogue. GÉNIE ÉLECTRIQUE (ELG) ELG 2136 Electronics I (3 units) Physics of semiconductors. Diodes: operation, models. and application circuits. Bipolar Junction Transistors - operation and characteristics. DC and AC circuit models. Basic single-stage BJT ampliﬁer conﬁgurations. Field-Effect Transistors: Structure and physical operation, bias circuits, small-signal equivalent circuits and basic ampliﬁers. Basic concepts of digital logic circuits. The BJT inverter. The CMOS Inverter. Propagation delay of the CMOS inverter. CMOS gates and other digital circuits. Introduction to Semiconductor Power Devices: thyristor, triac, Insulated Gate Bipolar transistor. Power Electronics Applications: The AC-DC, DC- DC, and DC-AC converters. Course Component: Laboratory, Lecture, Tutorial Prerequisite: ELG 2138. ELG 2137 Circuit Theory II (3 units) Ideal operational ampliﬁers - analysis and applications. Forced and natural responses of RLC circuits using the differential equation approach. Transient circuit analysis using unilateral Laplace transforms. Two-port networks and parameters. Mutual inductance and the ideal transformer. Transfer functions. Frequency response of simple ﬁlters. Fundamentals of computer-aided circuit simulation. The measurement of sinusoidal and non-sinusoidal electrical quantities in analogue and digital circuits. Introduction to sensors and instrumentation ampliﬁers. The measurement of non-electrical quantities. Course Component: Laboratory, Lecture, Tutorial Prerequisites: ELG 2138, MAT 2384. ELG 2138 Circuit Theory I (3 units) DC and sinusoidal steady state (AC) analysis of circuits. Basic passive circuit elements (resistors, capacitors, inductors). Voltage and current sources. Kirchoff laws. Loop and nodal analysis. Circuit theorems: Superposition, Maximum power transfer, Thevenin, Norton. Forced and natural responses of RL and RC circuits using the differential equation approach. Sinusoidal signals, complex numbers, phasors and impedance concepts. Average and RMS quantities. Steady state time-domain behaviour of inductors and capacitors. Complex, average and apparent power. Introduction to the use of electrical measurement equipment such as voltmeters, ammeters, wattmeters, function generators and oscilloscopes. Voltage, current and impedance measurement. Course Component: Laboratory, Lecture, Tutorial Prerequisites: ITI 1100, MAT 1341, MAT 1322. ELG 2336 Electric Circuits and Machines for Mechanical Engineering (3 units) Network theorems. Forced and transient response to deterministic inputs. Sinusoidal steady-state response of circuits. Magnetic theory and circuits. Transformers. Electromechanical energy conversion. Introduction to AC circuits, three phase power. DC machines, AC machines, torque-speed curves and efﬁciency. Laboratory experiments. Course Component: Laboratory, Lecture Prerequisite: PHY 1122. MAT 2384 is corequisite to ELG 2336. ELG 2536 Électronique I (3 crédits) Physique des semi-conducteurs. Diodes : fonctionnement, modèles et circuits dapplication. Transistors Bipolaires à Jonctions - fonctionnement et caractéristiques. Circuits équivalents en cc et en ca. Conﬁgurations de base d'ampliﬁcateurs TBJ à un étage. Transistors à Effet de Champ : structure et fonctionnement physique, circuits de polarisation, circuits équivalents à faible signal et conﬁgurations de base d'ampliﬁcateurs. Concepts fondamentaux de circuits logiques. Inverseur TBJ. Inverseur CMOS. Délai de propagation de l'inverseur CMOS. Portes logiques CMOS et autres circuits numériques. Introduction aux composants semi- conducteurs de puissance : thyristor, triac, Transistor bipolaire à porte isolée. Applications en électronique de puissance : les convertisseurs ca- cc, cc-cc et cc-ca. Volet : Tutoriel, Laboratoire, Cours magistral Préalable : ELG 2538. ELG 2537 Théorie des circuits II (3 crédits) Ampliﬁcateurs opérationnels idéaux-analyse et applications. Réponses naturelles et forcées de circuits RLC en utilisant l'approche par équations différentielles. Analyse transitoire de circuits par la transformée de Laplace unilatérale. Circuits à deux portes et leurs paramètres. Inductance mutuelle et transformateur idéal. Fonctions de transfert. Réponse en fréquence de ﬁltres simples. Fondements de la simulation de circuits assistée par ordinateur. Mesures de grandeurs sinusoïdales et non sinusoïdales dans les circuits analogiques et numériques. Introduction aux capteurs et ampliﬁcateurs pour instrumentation. Mesures de grandeurs non électriques. Volet : Laboratoire, Cours magistral, Tutoriel Préalables : ELG 2538, MAT 2784. ELG 2538 Théorie des circuits I (3 crédits) Analyse en régime permanent de circuits en courant continu et en courant alternatif. Éléments passifs de base des circuits (résistances, capacités, inductances). Sources de tension et courant. Lois de Kirchoff. Analyse par méthodes des mailles et des noeuds. Théorèmes pour les circuits : Superposition, transfert maximal de puissance, Thévenin, Norton. Réponses naturelles et forcées de circuits RL et RC en utilisant l'approche par équations différentielles. Signaux sinusoïdaux, nombres complexes, notions de phaseurs et impédances. Grandeurs moyennes et efﬁcaces. Comportement des inductances et capacités en régime permanent dans le domaine temporel. Puissance complexe, moyenne et apparente. Introduction à l'utilisation d'équipement de mesures électriques tels que les voltmètres, ampèremètres, générateurs de fonctions et oscilloscopes. Mesures de courant, tension et impédance. Volet : Laboratoire, Cours magistral, Tutoriel Préalables : ITI 1500, MAT 1741, MAT 1722. ELG 2736 Circuits et machines électriques pour ingénieurs en mécanique (3 crédits) Théorèmes de réseaux. Réponse transitoire et réponse forcée pour excitations déterministes. Régime sinusoïdal permanent des circuits. Théorie et circuits magnétiques. Transformateurs. Conversion électromagnétique de l'énergie. Introduction aux circuits en c.a. et à la puissance triphasée. Moteurs à c.c., moteurs à c.a., courbes couple- vitesse et efﬁcacité. Expériences au laboratoire. Volet : Laboratoire, Cours magistral Préalable : PHY1522. MAT2784 est concomitant à ELG 2736. http://catalogue.uottawa.ca/fr/cours/elg/index.html 1 Vous consultez la version 2019-2020 du catalogue. ELG 2911 Pratique professionnelle en ingénierie et technologie de l'information / Professional Practice in Information Technology and Engineering (3 crédits / 3 units) Histoire de la profession d'ingénieur. Principes de professionnalisme dans la pratique de l'ingénieur. Obligations éthiques et légales de l'ingénieur envers la société et l'environnement. Compétences requises en communication et administration dans la pratique de l'ingénieur. Santé et sécurité au travail. / History of the profession of engineering. Principles of professional engineering practice. Ethical, societal, environmental and legal obligations of the professional engineer. Communication and management skills required by the practicing engineer. Workplace health and safety. Volet / Course Component: Cours magistral / Lecture, Tutoriel / Tutorial ELG 3106 Electromagnetic Engineering (3 units) Transmission lines: time and space dependence of signals, line parameters, input impedance, use as circuit elements, reflection coefﬁcient, standing-wave ratio, transient behaviour. Impedance matching: transformers, stubs, analysis using the Smith Chart. Maxwell's and wave equations. Electromagnetic waves: TEM, TE, TM propagation. Waveguides: basic equations, parallel plate guide, rectangular guide. Introduction to antennas. Applications to communications and radar systems. Course Component: Laboratory, Lecture, Tutorial Prerequisites: MAT 2322, MAT 2384, PHY 2323. ELG 3125 Signal and System Analysis (3 units) Continuous-time and discrete-time signals. Mathematical description of systems. Properties of systems. Convolution and impulse response of continuous and discrete time LTI systems. Fourier series of periodic continuous and discrete time signals. Decomposition and approximation of signals by orthogonal functions. The Fourier transform of continuous and discrete time signals. Frequency response of systems. Frequency selective ﬁltering. First and second order systems. Sampling and interpolation of continuous-time signals. LTI system analysis with Laplace transforms. Course Component: Laboratory, Lecture, Tutorial Prerequisite: ELG 2138. ELG 3126 Random Signals and Systems (3 units) Probabilistic models, conditional probability and Bayes' rule; vectors of random variables, distributions and density functions, expectations and characteristic functions. Independence, Laws of Large Numbers, Central- Limit Theorem. Random process concepts. Random signal analysis concepts. Applications drawn from power systems, analog and digital circuits, communication systems and manufacturing. Course Component: Laboratory, Lecture, Tutorial Prerequisite: ELG 3125. The courses ELG 3126, MAT 2377 cannot be combined for units. ELG 3136 Electronics II (3 units) Differential Ampliﬁers: BJT, MOS. Multistage Ampliﬁers: Frequency Response: s-Domain analysis, ampliﬁer transfer function, frequency response of CS, CE, CB, cascode, CC and cascaded ampliﬁers. Feedback: general feedback structure and basic feedback topologies. Stability, frequency compensation Output Stages and Power Ampliﬁers: Class A, B and AB output stages. IC and MOS power ampliﬁers. Course Component: Laboratory, Lecture, Tutorial Prerequisite: ELG 2136. ELG 3137 Fundamentals of Semiconductor Devices (3 units) Modern solid-state electronic devices, their principles of operation, and fabrication. Solid state physics fundamentals, free electrons, band structure, and transport properties of semiconductors. Nonequilibrium phenomena in semiconductors. p-n junctions, Schottky diodes, bipolar and ﬁeld-effect transistors. Modern, high-performance devices. Ultrafast devices. Course Component: Laboratory, Lecture, Tutorial Prerequisites: ELG 2136, MAT 2384, (PHY 1124 or (PHY 1121, PHY 1122)). ELG 3155 Introduction to Control Systems (3 units) Introduction to control systems, dynamic systems modeling. Laplace transforms, partial fraction methods. Block diagram and signal flow graph models, transfer functions of linear systems. Introduction to state-space models. Feedback control system characteristics, stability and Routh-Hurwitz criteria, the root locus method, design of industrial controllers, the Nyquist stability criterion, Bode plots, design indexes, lead and lag controllers. Course Component: Tutorial, Laboratory, Lecture Prerequisite: ELG 3125. ELG 3175 Introduction to Communication Systems (3 units) Review of linear systems, the sampling theorem, and Fourier analysis. Noiseless analysis of the linear modulation schemes: double sideband, inphase-quadrature, single sideband, vestigial sideband and conventional AM. Superheterodyne receivers. Angle modulation: phase modulation, and frequency modulation. Carson's rule. Discriminator and phase-locked loop detection of FM. Basic digital modulation techniques: ASK, PSK, FSK. Bandwidth requirements of PAM (Nyquist's criterion). Pulse code modulation and companding. Introduction to error control coding and to information theory. Course Component: Laboratory, Lecture, Tutorial Prerequisite: ELG 3125. ELG 3126 is corequisite to ELG 3175. ELG 3316 Electric Machines and Power Systems (3 units) Machinery principles. Three-phase systems, transformers. AC machinery fundamentals, synchronous generators, synchronous motors, induction motors. DC machinery fundamentals, dc motors and generators, uploads/Litterature/ elg-pdf.pdf