MASTER OF ENGINEERING Introduction The Master of Engineering Program was offered in June, 1995 under the flagship of the DOST-ESEP I project to upgrade the engineering education in the Philippines. It was conceived by the consortium of DOST-ESEP network schools in the Visayas and Mindanao. These schools are Central Philippine University for Western Visayas, University of San Carlos for Central and Eastern Visayas, MSU-Iligan Institute of Technology for Northern Mindanao, and Ateneo de Davao and University of Mindanao for Southern Mindanao. Since its founding, the program has helped increase the number of engineering faculty members with advanced degrees. A number of graduates have been conferred the degree with specialization in such fields as Ceramics Engineering, Electrical Engineering, Electronics and Communications Engineering, Environmental Engineering, Material Science and Engineering, Mechanical Engineering and Metallurgical Engineering. Objectives The MOE program is offered with the following objectives: 1. to upgrade engineering education in the Visayas and Mindanao by making the program accessible to faculty members of engineering schools; and 2. to provide engineering practitioners advanced tools to cope with the increasing sophistication of processes and system in industries.
MASTER OF ENGINEERING (MOE) (LIST OF COURSES BY SEMESTER) First Year, First Semester Course Hrs/Wk Course Title Units No. Lec Lab Total ES 201 Advanced Engineering Mathematics I 3 3 0 3 ES 81 ES 210 Probability and Statistical Concepts in Engineering Planning and Design 3 3 0 3 ES 85 ES 215 Computer Programming 3 2 3 5 ES 81 ES 218 Energy Management 3 3 0 3 None Total 12 11 3 14 First Year, Second Semester Course No. Course Title Units Hrs/Wk Lec Lab Total ES 205 Numerical Methods for Engineers 3 3 0 3 ES 81 ES 216 Operations Research 3 3 0 3 None ES 217 Research and Development 3 3 0 3 ES 81 ES 219 Environmental Engineering and Management 3 3 0 3 None Total 12 12 0 12 Second Year, First Semester Course No. Course Title Units Hrs/Wk Lec Lab Total ES 202 Advanced Engineering Mathematics II 3 3 0 3 ES 201 ES 211 Experimental Analysis and Design 3 3 0 3 ES 210 (Discipline Related Course) 3 3 0 3 (Discipline Related Course) 3 3 0 3 Total 12 12 0 12 Second Year, Second Semester Course No. Course Title Units ES 220 Management Information Systems Hrs/Wk Lec Lab Total 3 3 0 3 None ES 221 Special Project 3 3 0 3 (Discipline Related Course) 3 3 0 3 (Discipline Related Course) 3 3 0 3 Total 12 12 0 12 All Foundation and General Courses
CATALOGUE OF COURSES FOUNDATION COURSES ES 201 ADVANCED ENGINEERING MATHEMATICS I Vector spaces, linear independence, matrices, rank and inverse of a matrix, decomposition theorems, eigenvalues and eigenvectors, unitary and similarity transformations on matrices, initial and boundary value problems, power series solutions. Applications to engineering problems. : ES 81 (Mathematical Methods in Engineering I) or equivalent ES 205 NUMERICAL METHODS FOR ENGINEERS Error analysis, solution of nonlinear equations, direct and iterative methods of solving linear systems, approximations of functions, numerical differentiation and integration, numerical solution of ordinary differential equations. With computer machine problems. : ES 81 (Math Methods in Engineering I) or equivalent ES 210 PROBABILITY AND STATISTICAL CONCEPTS IN ENGINEERING PLANNING AND DESIGN Basic probability and statistics with application and examples in engineering systems, elementary probability theory, random variables and their distributions, random processes, statistical inferences, curve fitting and prediction, correlation and application to quality assurance reliability life testing. : ES 85 (Probability and Statistics in Engineering) or equivalent ES 211 EXPERIMENTAL ANALYSIS & DESIGN Review of the fundamentals of statistics and probability. Review of regression analysis: linear and multiple regression analysis of variance. Design of experiments: completely randomized design, randomized complete blocks. Latin square multiclassification, factorial, incomplete blocks and fractional replications, confounding, general mixed factorials, optimum design. : ES 210 (Probability and Statistical Concepts in Engineering Planning and Design) or equivalent ES 215 COMPUTER PROGRAMMING Elements of computer programming, structured computer programming in FORTRAN or C, or any structured programming language. : ES 81 (Mathematical Methods in Engineering I) or consent of the instructor
ES 216 OPERATIONS RESEARCH Operations research methods. Linear programming, transportation problem, assignment problem, integer programming. Review of probabilities, network analysis, PERT-CPM, dynamic programming, game theory, MARKOV chains, nonlinear programming. ES 217 RESEARCH AND DEVELOPMENT Elements and fundamentals of research and development, writing of project proposals. : ES 81 (Mathematical Methods in Engineering I) ES 218 ENERGY MANAGEMENT Energy resources, conversions, uses. Energy conservation methods in the home, in transportation, in industrial and commercial sectors. Interfuel substitution; Factors in the design of low energy consumption buildings. Economics of energy. Technological, economic, societal and environmental factors. ES 219 ENVIRONMENTAL ENGINEERING & MANAGEMENT Pollution control laws; regulations and standards; types sources and harmful effects of pollution, solid and liquid waste disposal and management, air pollution control CORE COURSES ES 202 ADVANCED ENGINEERING MATHEMATICS II Boundary value problems of differential equations. Sturm-Liouville theory, singular boundary conditions, orthogonal expansions, separation of variables in partial differential equations, spherical harmonics. : ES 201 (Advanced Engineering Mathematics I) or equivalent ES 220 MANAGEMENT INFORMATION SYSTEMS The course covers the role of information system in governing the behavior of an organization. Topics include planning and control system, the role of analytical and simulation models in decision-making, the economics of information, and the implementation of an integrated system. Examples of some types of information system will be studied and their analysis and design will be discussed through cases and projects.
ES 221 SPECIAL PROJECT : All foundation courses & general courses ELECTRICAL ENGINEERING COURSES EE 212 LINEAR SYSTEMS THEORY Functions of matrices. State-space descriptions, canonical realizations, observability and controllability. Linear state-variable feedback, quadratic regulator theory. Asymptotic observers, direct transfer function design procedures. Synthesis of multivariable transfer functions. : Consent of the instructor EE 213 LINEAR NETWORK SYNTHESIS Positive real lemma. Bounded real lemma. Impedance matrix synthesis. Scattering matrix synthesis. Transfer function matrix synthesis. : EE 212 (Linear Systems Theory) EE 235 NONLINEAR SYSTEMS Methods of analysis and synthesis. Describing functions. Second method of Lyapunov. Popov and the circle criteria : EE 131 (Control Systems Theory) EE 245 ADVANCED THEORY OF ELECTRICAL MACHINES Generalized machine theory. Analysis of rotating machines during steady-state, transient and dynamic conditions. : EE 42 (Electromechanical Energy Conversion) EE 250 DIRECT ENERGY CONVERSION Photovoltaic generators. Thermionic converters. Magnetohydrodynamic generators. Fuel cells. Recent developments. : EE 151 (Introduction to Power Systems) EE 251 FAULT STUDIES Symmetrical components. Sequence impedances of transmission lines, synchronous machines and transformers. Unbalanced and simultaneous faults. : EE 151 or equivalent
EE 252 COMPUTER APPLICATIONS IN POWER SYSTEMS Network matrices. Mathematical models. Computer solution for load flow and fault studies. Sparsity techniques. Recent developments. : EE 151 or equivalent EE 254 SURGE PROTECTION IN POWER SYSTEMS Electrical surges including traveling waves due to lightning and switching. Principles of lightning protection. Insulation coordination. : EE 102 (Probability for Electrical Engineers) EE 256 PROTECTIVE RELAYING Fundamental principles. Protective devices. Relay systems. Relay coordination. : EE 251 (Fault Studies) EE 290 SEMINAR : 1 unit per semester; maximum of 3 units EE 353 POWER SYSTEM RELIABILITY Basic concepts. Measures and models. Reliability of generation, transmission, distribution and composite systems. : Consent of Instructor EE 357 POWER SYSTEM STABILITY Power system stability criteria. Steady-state, transient and dynamic stability. Swing equation. Computer solutions. Multi-machines. Recent developments EE 358 : Consent of Instructor POWER SYSTEM ECONOMICS Economics of energy generation and operation. Optimization methods. Mixedgeneration dispatch. Optimal load flow. Recent developments. : 3 units : Consent of Instructor EE 359 POWER SYSTEM OPERATION & CONTROLS Synchronous machines and their control systems. Excitation and speed governing systems. Prime movers. Load-frequency control. System voltage control. : EE 245 (Advanced Theory of Electrical Machines)
EE 258 LOAD FLOW STUDIES ELECTRONICS AND COMMUNICATIONS ENGINEERING COURSES ECE 205 DIGITAL SIGNAL PROCESSING Analysis of discrete signals and systems. Applications to digital filtering, active filters, digital communication and encoding. ECE 304 INTRODUCTION TO THE DESIGN OF DIGITAL COMPUTERS The hardware organization of computer systems including the following topics: Instruction set selection, arithmetic/logic unit design, hard wired and microprogrammed control schemes, memory organization. I/O interface design. The course will involve computer simulation of digital systems. ECE 201 INTRODUCTION TO DIGITAL SIGNAL PROCESSING An introductory treatment of digital signal processing algorithms and implementation using high speed digital signal processors. Detailed discussions of sampling, architecture, addressing modes and instruction set of digital signal processors, discrete Fourier transform and digital filtering. ECE 251 SEMICONDUCTOR POWER ELECTRONICS Introduction to power semiconductor devices, characteristics and ratings. Analysis and design of circuits with power semiconductors and associated devices are emphasized. Topics include power rectification, inversion, AC-to-DC power control, firing circuits and microcomputer control of power circuits. ECE 227 INTRODUCTION. TO COMMUNICATIONS SYSTEMS ANALYSIS Applications of the principles of signal analysis of amplitude phase, and frequency modulator systems. Behavior of receivers in the presence of noise. Pulse code modulation and multiplex systems. Emphasis on applications of theory to communication system design. ECE 277 DIGITAL COMPUTATIONAL TECHNIQUES FOR ELECTRONIC CIRCUITS Algorithmic and computational aspects of electronic circuit analysis. Both linear and nonlinear. Numerical methods such as Newton-Raphson and various integration formulas. Sparse matrices and implicit integration techniques. Worst case and tolerance analysis.
ECE 281 DESIGN OF ANALOG AND DIGITAL FILTERS Approximation of filter transfer characteristics, scaling, and transformations in digital filter design. Active filter design using OP-Amps; Sensitivity calculations and minimization; Computer-aided methods. ECE 285 INTEGRATED CIRCUIT ENGINEERING Analysis, design, and fabrication of silicon, thin-film and thick-film integrated circuits. Consideration of circuit design, layout and fabrication techniques for integrated circuits. Circuit simulation studies are aided with SPICE II software system. Integrated operational amplifiers and logic gates (T2L, I2L, MOS, and CNOS) are treated. ECE 305 INTRODUCTION. TO COMPILERS AND TRANSLATION ENGINEERING The design and construction of compilers and other translators. Topics include compilation goals, organization of a translator, grammars and languages, symbol tables, lexical analysis, syntax analysis (parsing), error handling, intermediate and final code generation, assemblies, interpreters, and an introduction to optimization/parallelization. Emphasis is on engineering, from scratch, a compiler or interpreter for a small programming language typically a C or Pascal subset. Projects involve the implementation (and documentation) of such a system using a C on ECN Unix. ECE 307 OPERATING SYSTEMS ENGINEERING The design and construction of modern operating systems. Basic process concepts in multiprogrammed computer systems including concurrency, scheduling, resource sharing, synchronization, deadlock, mutual exclusion and protection. The engineering of operating systems involving detailed examination and modification of an existing operating system, Unix. Presentation of analytic modeling and performance evaluation techniques. Case studies of existing operating systems. A substantial part of the course will involve projects centered on modification of Unix. The projects will support concepts of OS design and construction including primary and secondary storage management, file systems, I/O subsystems, CPU scheduling, and disk scheduling. ECE 255 OPTIMIZATION METHODS FOR SYSTEMS AND CONTROL Introduction to various methods of obtaining the extremum of a nondynamic or dynamic system and their uses in control system design. Linear programming, various search methods, nonlinear programming, and dynamic programming are presented for discrete-time as well as continuous-time systems. Various real-life applications are discussed, and appropriate case studies are investigated
ECE 257 INTRODUCTION TO ANALYSIS OF NONLINEAR SYSTEMS Applications of phase plane methods and classification of singular points. Iteration and perturbation techniques jump resonance. Limit cycles. Relaxation oscillations. Introduction to Liapunov and asymptotic stability. Control area staff. ECE 263 INTRODUCTION TO MODERN CONTROL THEORY Theoretical methods in optimal control theory. Topics include the calculus of variations and the Pontryagin minimum principle with applications to minimum energy problems. Geometric methods will be applied to the solution of minimum time problems. Computational methods, singular problems, observer theory, and sufficient conditions of existence of solutions are also discussed. ECE 282 DIGITAL COMMUNICATIONS Introduction to digital communication systems and spread spectrum communications. Topics include analog message digitization, signal space representation of digital signals, binary and M-ary signals, comparison of digital communication systems in terms of signal energy and signal band width requirements. The principal types of spread spectrum systems are analyzed and compared. Application of spread spectrum to multiple access systems and to secure communication system is discussed. ECE 231 INTRODUCTION TO NEURAL NETWORKS An introduction to basic concepts in the design, analysis and application for computational neural networks. Topics include highly parallel fine grain architectural model such as the Boltzman machine, Rosenblatt s perception, Hopfield s neutral nets, Back propagation, and their associated learning algorithms. Proposed architectures and related simulation techniques are discussed. Applications to signal/image processing and recognition optimization, and controls are examined. ECE 285 DIGITAL IMAGE PROCESSING Introduction to digital image processing techniques for enhancement, compression, restoration, reconstruction, and analysis, 2-D signals and systems; sampling and scanning; random fields; discrete cosine transform; discrete Karhunen-Loeve transform; grayscale transformations; linear, ranked order, and morphological filters; human vision, printing, and display of images, entropy-based compression; vector quantization; block truncation coding; transform coding; predictive coding; image degradation models; Wiener filter; constrained deconvolution, computed tomography; edge detection; shape representation; and segmentation.
ECE 267 ELECTRONIC INSTRUMENTATION AND CONTROL CIRCUITS Analysis and design of special amplifiers, pulse circuits, operational circuits, DC amplifiers, and transducers used in instrumentation, control, and computation. ECE 308 COMPUTER ARCHITECTURE An introduction to the problems involved in designing and analyzing current machine architectures. Included are stack, SIMD, and MIMD machines, and the use of overlap, pipeline, parallel, and associative processing. Advanced I/O systems and memory organizations are examined. Evaluation methods for the performance of computer systems to enable the architect to determine the relation between a computer design and the design goals are explored. Some programming experience is assumed. MATERIALS SCIENCE AND ENGINEERING COURSES MSE 242 HIGH TEMPERATURE ALLOYS Theory of alloying and relationship among temperature, structure, and mechanical properties in nickel, cobalt, and iron base alloys are presented. Effects of thermomechanical processing are shown. Analysis of microscopy, scanning electron microscopy, x-ray diffraction and x-ray microprobe are discussed. MSE 241 CORROSION Rate-controlling steps in electrode processes, nature, structure, and mechanical properties in nickel; activation, ohmic, and concentration polarization; passivation; potentio-static studies and alloy design; application to engineering systems. MSE 210 TRANSPORT PHENOMENA IN SOLIDS Energetics and kinetics of phase change in metals and alloys. Nucleation and growth models, with special emphasis on role of crystal defects. Selected topics in multicomponent diffusion. MSE 261 POLYMER SCIENCE Fundamental relationships between chemical structure and physical properties of high polymers. Polymerization reactions and processes. Molecular weight, viscous flow and mechanical properties of polymers.
METALLURGICAL ENGINEERING COURSES MetE 222 ADVANCED MINERAL DRESSING Special topics in flotation and comminution theory, mineral physics, thermal description, rise of radioactive tracers and ion exchange resins. MetE 234 ADVANCED PRODUCTION OF IRON AND STEEL Technology of steel making; blast furnace operation; converter operation, open hearths process, direct reduction process, Correx process and other processes. MetE 240 WELDING METALLURGY Welding processes, thermal aspects of welding. Metallurgical evaluation of the microstructure resulting from welding; Phase transformation during welding; Selection of filler metals, Stresses; Stress relief and annealing; Preheating and post heating, difficulties and defects; welding ferrous and non-ferrous alloys; welding tests. MetE 241 ADVANCED PHYSICAL METALLURGY Electron theory of metals, the nature of solid solutions, intermetallic compound, solid state transformations mechanism of plastic deformation, creep, fatigue, rupture of metals. MetE 253 FUELS AND COMBUSTION Properties of different fuel materials; combustion processes; flame propagation phenomena; application of the concepts of heat transfer and combustion to the design and industrial furnaces; and estimation of energy requirements of different metallurgical processes. of commercial MetE 281 DISLOCATION THEORY Foundations of dislocation theory, dislocation movements, forces, interactions, role of dislocations in strengthening mechanism in solids.
CERAMICS ENGINEERING COURSES CerE 201 X-RAY CRYSTALLOGRAPHY X-ray methods for the characterization of crystal structure and determination of chemical composition. CerE 210 REFRACTORIES AND FURNACES Classification of refractories and their application to industries, study of the physical and chemical properties of refractories, and of pertinent phase equilibrium systems, manufacture, refractory utilization practices; industrial furnaces. MECHANICAL ENGINEERING COURSES ME 252 GAS DYNAMICS Fundamentals of gas dynamics. Steady one-dimensional flow. Shock regions. Introduction to propulsion systems. ME 253 COMBUSTION Physical and chemical aspects of basic combustion phenomena. Classification of flames. Measurement of laminar flame speeds. Factors influencing burning velocity. Theory of flame propagation. Flammability, chemical aspects, chemical equilibrium, chain reactions. Calculation and measurement of flame temperature. Diffusion flames. Fuels-atomization and evaporation of liquid fuels. Theories of ignition, stability, and combustion efficiency. ME 254 THERMAL ENGINEERING Characteristics of gaseous, liquid and solid fuels. Local materials. Efficient burning of fuels in furnaces, kilns, gas producers, engine and other heat engine. Performance calculations. Treatment of fuel to improve its suitability for a given heat equipment. ME 255 ADVANCED HEAT CONDUCTION Steady and transient heat conduction. Stationary and moving sources. Numerical and graphical methods. Porous systems. : ES 202 (Advanced Engineering Math II) or consent of Instructor
ME 256 ADVANCED HEAT CONVECTION Mechanism of fluid flow, energy relationship of flowing fluid. Convection heat transfer. Momentum, heat and mass transfer analogies. Boiling and condensing heat transfer. : ES 202 (Advanced Engineering Mathematics II) or consent of Instructor ME 257 ADVANCED HEAT RADIATION Radiation heat transfer. Shape factors in an absorbing and non-absorbing media. Thermal radiation from gases and flames. : ES 202 (Advanced Engineering Mathematics II) or consent of Instructor ME 258 TWO-PHASE FLOW & HEAT TRANSFER Nature of multiphase flow. An intensive study of flow patterns in multi-component flows and the application of these principles to pipe design. Modeling of two-phase flow in vertical, horizontal and inclined pipes. Two-phase flow in adiabatic pipes and heated pipes. Correlation of pressure changes and heat transfer in pipes. The prediction of gaseous and liquid diffusion coefficients. : ES 202 (Advanced Engineering Mathematics II) and ME 256 (Advanced Heat Convection) ME 259 THERMAL SCIENCE APPLICATION IN POWER ENGINEERING Power system thermodynamics. Power plant cycles; processes; and components, combustion equipment, heat exchangers, turbines, and pumps. Water supply and treatment systems. Air circulating and heating systems. Operation, efficiency and energy balance calculations of power stations. Economics and management of power production. Environmental impacts of thermal plants. ME 260 ADVANCED DYNAMICS Generalized coordinates, classification of dynamical systems with finite degrees of freedom. Lagrange equations for rheonomic, non-holoromic systems. Ignorable coordinates, small oscillations about steady solutions, and introduction to stability. ME 261 CONTINUUM MECHANICS I Introduction to Cartesian tensor. Basic principles of continuum mechanics; concepts of deformation, motion, stress, and strain; conservation of mass, balance of momenta, continuum thermodynamics, and constitutive equations. Illustrative applications in elasticity, fluid dynamics, and viscoelasticity.
ME 262 ADVANCED STRESS ANALYSIS Studies of stresses and strains in three-dimensional problems. Failure theories and yield criteria. Stress function approach to two-dimensional problems. Bending of non-homogeneous asymmetric curved beams. Torsion of bars with non-circular cross sections. Energy methods. Elastic stability. Introduction to plates. ME 263 FINITE ELEMENT ANALYSIS After the concepts of finite elements methods are presented, formulation for different engineering problems and their applications are studied. Topics include variational methods. The finite element concept, and applications in stress analysis, dynamics, fluid mechanics, and heat transfer. ME 264 ADVANCED KINEMATICS Geometry of constrained plain motion with application to linkage design. Type and number synthesis, size synthesis. Path curvature, inflection circle, cubic of stationary curvature. Finite displacements, three-andfour-separated positions. Graphical, analytical, and computer techniques. ME 265 INTERACTIVE COMPUTER GRAPHICS The principles of computer graphics and interactive graphical methods for problem solving. Emphasis is placed on development and use of graphical tools for various display devices. Topics include pen plotting, storage tube, three dimensions color, modeling of geometry, and hidden surface representation of systems, controllability and observability, stability, probability and random signals, correlation, autocorrelation, and spectral density. Modeling technique and design of controllers using digital and analog controllers. : ES 202 & Vector Analysis and Complex Variables ME 266 COMPUTATIONAL FLUID DYNAMICS Application of finite difference methods, finite element methods, and the method of characteristics for the numerical solutions of fluid dynamics problems. Incompressible viscous flows: vorticity transport equation, stream function equation, and boundary conditions. Compressible flows: treatment of shocks, implicit and explicit artificial viscosity techniques, and boundary conditions. Computational grids. Graphical methods for problem solving. Emphasis is placed on development and use of graphical tools for various display devices. : ES 202 (Advanced Engineering Mathematics II) or consent of Instructor
ME 267 MECHANICAL VIBRATIONS Linear vibration analysis of multi-degree-of-freedom systems. Torsional vibrations in gears and shaft systems. Finite elements analysis of machine members dynamics. Introduction to experimental vibration analysis using Fast Fourier Transform (FFT) techniques. Typical sources of vibration in machines. Experimental modal analysis. : ES 202 (Advanced Engineering Mathematics II) or consent of Instructor ME 268 ANALYSIS OF PLATES AND SHELLS Bending of rectangular and circular plates under normal loading; thermal stresses in plates. Stresses in thick and thin shells; bending and thermal stresses at joints. Design of pressure vessels. ENVIRONMENTAL ENGINEERING COURSES EnE 203 ENVIRONMENTAL ENGINEERING BIOLOGY Freshwater biology; self-purification of streams; effect of thermal pollution; roles of organisms in trickling filtration and activated sludge; enzyme stabilization of organic matter. : Consent of Instructor EnE 210 ENVIRONMENTAL ENGINEERING LABORATORY I Examination and analysis of water and sewage as related to their treatment : 3 units (1 hr lec; 6 hrs lab) : Chem 16 (General Chemistry II) EnE 215 ENVIRONMENTAL MEASUREMENTS AND ANALYSIS A field and laboratory course designed to acquaint students with basic techniques needed to measure an analyze various biotic and abiotic environmental parameters in estuarine and shallow habitats. : 3 units (1 hr lec; 6 hrs lab) : Consent of Instructor EnE 216 ECOSYSTEM ANALYSIS Formulation and simulation of compartment models of marine and terrestrial ecosystems with complex nutrient cycling, food chains and energy flow; analog and digital simulation techniques; ecosystem stability and sensitivity, organization, structure and diversity of an ecosystem. : Consent of Instructor
EnE 217 ENVIRONMENTAL IMPACT ASSESSMENT Framework and methodology of environmental impact assessment; prediction and assessment of impacts on the physical and biological environment, assessment of environmental resources in terms of their potential for utilization and corresponding impact to human activities : 4 units (3 hrs lec; 3 hrs lab) : Consent of Instructor EnE 221 WASTEWATER DISPOSAL AND TREATMENT Wastewater characteristics; stream pollution load; sewerage systems; physical and other waste water treatment methods. : ES 219 EnE 231 WATER QUALITY MANAGEMENT Methods and economics of water quality control; river and estuary models for water. : Consent of Instructor EnE232 SOLID WASTE MANAGEMENT Composition and quantity of solid wastes generated by residential, commercial and industrial establishments, disposal methods and management : Consent of Instructor EnE 233 ECOSYSTEM MODELING AND RESOURCE MANAGEMENT Concepts in systems ecology and ecological modeling with emphasis on the use of models and computer simulations in examining environmental interactions; predicting environmental impact and facilitating the process of environmental planning. : ES 201 or Consent of Instructo EnE 234 AIR QUALITY MANAGEMENT Nature, sources, effects and control of air pollutants, sampling and analysis; monitoring meteorology. EnE241 BIOLOGICAL TREATMENT PLANT DESIGN Theory of biological treatment processes and design of treatment plants. : EnE 203 (Environmental Engineering Biology)
EnE 242 CHEMICAL TREATMENT PLANT DESIGN Theory of chemical treatment processes and design of treatment plants. : EnE 203 (Environmental Engineering Biology)