Experimental methods course is presented as a process of investigation starting with an observation, leading to one or more hypotheses tested by experiments involving measurements, collection of results, analysis and conclusion. Students are first introduced to the historical significance of experimental discoveries, the importance of experimental design and measurement.
Key examples are discussed. The importance of measurements, errors, uncertainty and its justification will be discussed in detail and students will learn how to estimate, use and report uncertainties.
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Techniques to compare, analyze and report different measurements are studied. Students are introduced to error propagation rules, random and systematic errors and standard deviation as the uncertainty in a single measurement. The measurement system in an engineering context and practical examples of measurement systems and how they work will be discussed, as will be professional ethics within this context. This course provides an introduction to the methods, techniques, theory, and application of numerical methods in the solution of engineering problems.
Topics to be covered include the following: finding roots of equations, numerical differentiation and integration, time marching methods in solving ordinary differential equations, and optimization. This course provides an introduction to electrical circuits. The course focuses on electrical circuits and components, passive and active filtering for signal conditioning, dynamic measurement system response characteristics, analog signal processing, digital representation, data acquisition, sensors, actuators and actuator characteristics.
Studies of measurement systems via computer simulation also are discussed.
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The laboratory experiments draw upon examples from all disciplines of engineering such as data acquisition, operational amplifiers, temperature measurement, and motion and force measurements. The course introduces students to the fundamentals of structural components analysis thus enabling them to employ that knowledge for structural analysis and for design of structural members.
Topics include: three-dimensional analysis of stress; torsion of thin-walled sections; inelastic torsion; analysis of composite and unsymmetric beams; inelastic bending; beam deflections; elastic buckling of columns; and strength failure criteria. The course provides an in-depth coverage of structural analysis techniques. Topics in this course include: analysis of statically determinate beams, frames and trusses; influence lines for determinate beams and trusses; deflection calculations using geometrical and energy methods; analysis of statically indeterminate structures using superposition; slope deflection; moment distribution; and matrix analysis of structures.
The course includes computer assignments using commercial structural analysis software. This course introduces water and wastewater treatment; stream assimilation and public health; introduction to air pollution and solid waste management; and laboratory analysis of water and wastewater samples and treatment process tests.
Students gain an understanding of the interrelatedness of environmental problems around the world and how different socioeconomic, technological, ethical, and other factors can impact both the environment and the approach to solving environmental problems.
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Factors and parameters affecting design of environmental systems are discussed and design in environmental engineering is introduced. The course introduces students to fundamental concepts that underlie highway design, traffic operations, and transportation systems planning and operations. The course begins with vehicle performance and the role it has to play in the design of highways.
Vehicle cornering, highway superelevation, and horizontal and vertical design of highways are introduced. The topics covered related to traffic operations include individual vehicle motion, elementary traffic characteristic relations, traffic dynamics, and traffic control.
Topics related to transportation systems include routing, dynamic programming and shortest path algorithms, network traffic management, and route choice. This course offers a detailed treatment of the design of reinforced concrete members. Topics include: material properties of reinforced concrete, American Concrete Institute ACI load and resistance factors; flexural design of beams and one-way slabs; shear and diagonal tension in beams; serviceability and reinforcement detailing; and design of reinforced concrete columns.
The course includes a design project in which students work in groups to simulate and solve specific design problems using structural analysis and design software.
This course presents an overview of fundamental data structures, which are commonplace in programming, as well as associated basic algorithms. Complexity analysis, linked lists, stacks, queues, trees, hashing, sorting, and basic graphs algorithms are covered. Practical lab exercises complement the lectures. The students further specialize and consolidate their knowledge through lab projects to demonstrate the operation and applications of various data structures.
The course introduces the principles of computer organization and basic architecture concepts. The course also covers performance and distributed system models. The labs emphasize experiential learning of computer organization and architecture concepts, and require students to use learned knowledge to create and build prototypes and evaluate their performance. This module covers analytical techniques for analyzing, characterizing and synthesizing engineering systems.
Systems approaches where the entire system or each of the sub-systems is considered as single units are introduced. Introductory topics in this course include: sinusoids, phase and time shift, and complex exponentials. Operations on sinusoidal signals include addition of signals with the same frequency via the phasor addition rule, conversion between time-shift and phase, and addition of signals with different frequencies via the introduction of the frequency spectrum concept.
Topics on discrete time systems include: FIR and IIR filtering, impulse response, causality, linearity, time invariance, and convolution. Time and frequency domain representations of systems and conversions between these representations are also studied. Z-transform domain, the concept of poles and zeros, stability and their relevance to the time and frequency domains are also covered.
Topics on continuous time systems include continuous-time convolution, the Laplace transform, Fourier analysis for continuous-time signals, and the Sampling theorem. This course focuses on fundamentals of electronics theory and design. The topics covered include semiconductor physics, diodes, diode circuits such as limiters, clamps; bipolar junction transistors; small-signal models; cut-off, saturation, and active regions; common emitter, common base and emitter-follower amplifier configurations; field-effect transistors MOSFET and JFET ; biasing; small-signal models; common-source and common gate amplifiers; and integrated circuit MOS amplifiers.
The laboratory experiments include the design, building and testing of diode circuits, including rectifiers, BJT biasing, large signal operation and FET characteristics, providing hands-on experience of design, theory and applications, with emphasis on small signal analysis and amplifier design. The course also covers the design and analysis of small-signal bipolar junction transistor and field-effect transistor amplifiers; and, diode circuits.
The students are introduced to designing and analyzing circuits using the LTPSpice or Cadence simulation tool. This course introduces students to the basic concepts of thermodynamics and their applications to engineering problems. The following topics are covered in this course: properties of pure substances; concepts of work and heat; closed and open systems; the fundamental laws of thermodynamics; Carnot and Clausius statements of the 2nd law; entropy and entropy production; heat engines, refrigerators, heat pumps; efficiencies, coefficients of performance.
This course introduces students to the fundamentals of machine elements thus enabling them to employ the knowledge gained to design machine elements for various engineering applications. The course is divided into two parts.
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In the first part, fundamental topics such as materials, stress, strain, deflection and failure are reviewed. In the second part, basic machine elements such as screws, springs, shafts are analyzed. Bearings, gears, belts, clutches and brakes are also discussed. This course provides an introduction to computer-aided design CAD using solid modeling. Students learn to create solid object models using extrusions, revolutions, and swept paths, and learn to modify parts using cutting, patterns, fillets, chamfers, and other techniques. Assemblies of multiple parts are used to demonstrate the need for geometric tolerances, and students spend a large portion of class in hands-on use of software tools.
The labs emphasize experiential learning of CAD concepts and applications using software tools. This course introduces students to vibrations of rigid bodies supported by an elastic component i. The course covers response of systems subjected to free, transient, and forced vibration situations. Starting with single-degree-of-freedom systems, the course progresses to modeling and analyzing the response of multiple-degree-of-freedom systems using analytical methods. Practical applications of this material include vibration isolation, suspension systems, and active vibration control.
The lab component includes vibration testing and modal analysis of structures subjected to impulse or harmonic excitation, and involves concepts such as digital acquisition of signals from accelerometers, signal conditioning and frequency spectrum analysis to determine the natural frequencies of the structure. This course introduces students to the basic principles and engineering applications of heat transfer. Fundamental concepts and principles of conduction, convection, and radiation heat transfer are introduced and the pertinent governing equations are developed.
This is followed by the application of these equations in analysis of heat transfer systems such as fins and heat exchangers. The following topics are covered in this course: introduction to conduction, convection, and radiation; one-dimensional, steady-state conduction; multi-dimensional, steady-state conduction; lumped capacitance method in transient conduction; one-dimensional transient conduction; introduction to convection; internal and external forced convection; and principles of radiative heat transfer.
This course focuses on the analysis and design of energy-conversion systems. It introduces students to power generation systems. Topics covered include gas and vapor power systems and their components; refrigeration and heat pump systems; combustion; boiling heat transfer characteristics; design of heat exchangers and cooling systems. Students gain an understanding of the fundamentals of such systems and the issues related to their operation from economic, environmental, ethical and safety points of view.
This course introduces students to the demands and pleasures of university-level investigation of literature. Students develop the tools necessary for advanced criticism, including close-reading skills, knowledge of generic conventions, mastery of critical terminology, and introduction to a variety of modes of analysis, from the formal to the historical. The course emphasizes the writing and revision strategies necessary to produce sophisticated literary analysis. Literary Interpretation - Sample Syllabus.