# College Of Engineering and Architecture

# College Of Engineering

### Mission

The College of Engineering and Architecture is committed to offering an international standard curriculum that addresses the demands of the engineering profession.

### Vision

The College of Engineering and Architecture is committed to offering an international standard curriculum that addresses the demands of the engineering profession.

##### MATH 1- COLLEGE ALGEBRA

Algebraic expressions and equations; solution sets of algebraic equations in one variable: linear, quadratic, polynomial of degree n, fractional, radical equations, quadratic in form, exponential and logarithmic equations; decomposition of fractions into partial fractions; solution sets of systems of linear equations involving up to three variables.

##### MATH2-PLANE AND SPHERICAL TRIGONOMETRY

Trigonometric functions; identities and equations; solutions of triangles; law of sines; law of cosines; inverse trigonometric functions; spherical trigonometry

##### MATH 3- ANALYTIC GEOMETRY

Equations of lines and conic sections; curve tracing in both rectangular and polar coordinates in two-dimensional space.

##### MATH4-SOLID MENSURATION

Concept of lines and planes; Cavalieri’s and Volume theorems; formulas for areas of plane figures, volumes for solids; volumes and surfaces areas for spheres, pyramids, and cones; zone, sector, and segment of a sphere; theorems of Pappus.

##### MATH 5- ADVANCED ALGEBRA

Matrices and determinants; arithmetic and geometric series; solution sets of different types of inequalities and systems involving quadratics; solution of linear equations using determinants and matrices.

##### MATH 6- DIFFERENTIAL CALCULUS

Basic concepts of calculus such as limits, continuity and differentiability of functions; differentiation of algebraic and transcendental functions involving one or more variables; applications of differential calculus to problems on optimization, rates of change, related rates, tangents and normal’s, and approximations; partial differentiation and transcendental curve tracing.

##### MATH7-INTEGRAL CALCULUS

Concept of integration and its application to physical problems such as evaluation of areas, volumes of revolution, force, and work; fundamental formulas and various techniques of integration applied to both single variable and multi-variable functions; tracing of functions of two variables.

##### MATH 8 – DIFFERENTIAL EQUATIONS

Differentiation and integration in solving first order, first-degree differential equations, and linear differential equations of order n; Laplace transforms in solving differential equations.

##### Math 9-ADVANCED MATHEMATICS FOR INDUSTRIAL ENGINEERING

Matrices, determinants, systems of linear and nonlinear equations, elements of error analysis, real roots of an equation, polynomial approximation by finite difference and least-squares methods, and numerical solution on systems of linear and nonlinear equations.

##### STAT 2- ADVANCED STATISTICS

Regression, correlation, and design of experiments and their applications in Industrial Engineering.

##### COMP1A- COMPUTER FUNDAMENTALS AND PROGRAMMING

Basic information technology concepts; fundamentals of algorithm development; high-level language and programming applications; computer solutions of engineering problems.

##### COMP2A- COMPUTER-AIDED DRAFTING

Concepts of computer-aided drafting (CAD); introduction to the CAD environment; terminologies; and the general operating procedures and techniques in entering and executing basic CAD commands.

##### DYNAMICS OF RIGID BODIES

Kinetics and kinematics of a particle; kinetics and kinematics of rigid bodies; work-energy method; and impulse and momentum.

##### ELEMENTARY ELECTRICAL ENGINEERING

Principles, basic laws, and theorems are used in analyzing electrical circuits in both direct current and alternating current conditions.

##### ENGINEERING DRAWING

Practices and techniques of graphical communication; application of drafting instruments, lettering scale, and units of measure; descriptive geometry; orthographic projections; auxiliary views; dimensioning; sectional views; pictorial drawings; requirements of engineering working drawings; and assembly and exploded detailed drawings.

##### ENGINEERING ECONOMY

Concepts of the time value of money and equivalence; basic economy study methods; decisions under certainty; decisions recognizing risk; and decisions admitting uncertainty.

##### ENGINEERING MANAGEMENT

Decision-making; the functions of management; managing production and service operations; managing the marketing function; and managing the finance function.

##### ENGINEERING VALUES AND ETHICS

Overview on values, value system, value formation, and value clarification processes; work and responsibilities of an industrial engineer; relations of the industrial engineer with the state, the public, the clients, employer, engineers, and other professionals

##### BSC ENG3-ENVIRONMENTAL ENGINEERING

Ecological framework of sustainable development; pollution environments: water, air, and solid; waste treatment processes, disposal, and management; government legislation, rules, and regulation related to the environment and waste management; and environmental management system.

##### ERGONOMICS

Origins and development of human factors and ergonomics. Movement, cognitive and environmental factors in ergonomic workplace design and evaluation. Tools and techniques of ergonomic risk assessment.

##### IE 511-FACILITIES PLANNING AND DESIGN

Principles and practice of the planning of facility layout and material handling equipment for manufacturing and service systems. Analytical approaches in site location, facility layout, material handling, and storage systems. Systematic procedures and computer-aided techniques

##### FINANCIAL ACCOUNTING

Accounting concepts and principles applied to service, merchandising, and manufacturing operations; partnerships and corporations; the analysis, interpretation, and use of accounting data for management.

##### CHEM1-GENERAL CHEMISTRY

Basic concepts of matter and its classification; mass relationships in chemical reactions; properties of gases, liquids, and solids; concepts of thermochemistry; the quantum theory and electronic behavior; periodic relationship of elements in the periodic table; intramolecular forces; and solutions.

##### INDUSTRIAL MATERIALS AND PROCESS

Industrial materials and processes and their effects on production system decisions. Metals, plastics, glass and ceramics, elastomers, wood, pulp, and other common engineering materials, their uses, and their production processes.

##### INDUSTRIAL QUALITY CONTROL

Natural and assignable variations, central limit theorem, process control, tools for process control, benefits of control charts, traditional control chart for variables, traditional control charts for attributes, process capability, and acceptance sampling.

##### IE513-INFORMATION SYSTEMS

Concepts and frameworks of information systems. Analysis and design of information systems.

##### MANAGERIAL ACCOUNTING

Uses accounting information for managerial planning and control.

##### MECHANICS OF DEFORMABLE BODIES

Axial stress and strain; stresses for torsion and bending; combined stresses; beam deflections; indeterminate beams; and elastic instability

##### METHODS STUDY

Productivity concepts and techniques. Methods study and work measurement. Wage payment. Indirect and expense labor standards. Training practices.

##### OPERATIONS RESEARCH 1

Operations research approach and methodology. Linear programming formulation and solution techniques, duality theory, sensitivity analysis; transportation and assignment problems; network models.

##### OPERATIONS RESEARCH 2

Integer linear programming, dynamic programming, queuing theory, decision theory, game theory, Markov theory.

##### PHYSICS 1

Vectors; kinematics; dynamics; work, energy, and power; impulse and momentum; rotation; dynamics of rotation; elasticity; and oscillation.

##### PHYSICS 2

Fluids; thermal expansion, thermal stress; heat transfer; calorimetry; waves; electrostatics; electricity; magnetism; optics; image formation by plane and curved mirrors; and image formation by thin lenses.

##### PRINCIPLES OF ECONOMICS

Introduction to economic theory and applications.

##### PROBABILITY AND STATISTICS

Basic principles of statistics; presentation and analysis of data; averages, median, mode; deviations; probability distributions; normal curves and applications; regression analysis and correlation; application to engineering problems.

##### PRODUCTION SYSTEMS

Analysis, design, and management of production systems. Productivity measurement, forecasting techniques, project planning, line balancing, inventory systems, aggregate planning, master scheduling, operations scheduling, and modern approaches to production management such as Justin-Time production.

##### PROJECT FEASIBILITY

Phases of project feasibility studies. Project development, evaluation, and management.

##### SAFETY MANAGEMENT

Evolution of safety management; safety terminology; safety programs adopted by high-risk industries; hazards in the construction, manufacturing, gas and power plants, and other engineering industries and how to prevent or mitigate them; techniques in hazard identification and analysis in workplaces; off-the-job safety; disaster prevention and mitigation; and incident investigation.

##### STATICS OF RIGID BODIES

Force systems; structure analyses; friction; centroids and centers of gravity; and moments of inertia.

##### SYSTEMS ENGINEERING

Total systems analysis and design. Integration of subsystems with a concentration on optimal total systems implementation.

##### THERMODYNAMICS

Thermodynamic properties of pure substances, ideal and real gases, and the study and application of the laws of thermodynamics in the analysis of processes and cycles. Introduction to vapor and gas cycles.

##### COLLEGE ALGEBRA

Algebraic expressions and equations; solution sets of algebraic equations in one variable: linear, quadratic, polynomial of degree n, fractional, radical equations, quadratic in form, exponential and logarithmic equations; decomposition of fractions into partial fractions; solution sets of systems of linear equations involving up to three variables.

##### PLANE AND SPHERICAL TRIGONOMETRY

Trigonometric functions; identities and equations; solutions of triangles; law of sines; law of cosines; inverse trigonometric functions; spherical trigonometry

##### ADVANCED ALGEBRA

Matrices and determinants; arithmetic and geometric series; solution sets of different types of inequalities and systems involving quadratics; solution of linear equations using determinants and matrices.

##### ANALYTIC GEOMETRY

Equations of lines and conic sections; curve tracing in both rectangular and polar coordinates in two-dimensional space.

##### SOLID MENSURATION

Concept of lines and planes; Cavalieri’s and Volume theorems; formulas for areas of plane figures, volumes for solids; volumes and surfaces areas for spheres, pyramids, and cones; zone, sector, and segment of a sphere; theorems of Pappus.

##### DIFFERENTIAL CALCULUS

Basic concepts of calculus such as limits, continuity and differentiability of functions; differentiation of algebraic and transcendental functions involving one or more variables; applications of differential calculus to problems on optimization, rates of change, related rates, tangents and normal, and approximations; partial differentiation and transcendental curve tracing.

##### INTEGRAL CALCULUS

Concept of integration and its application to physical problems such as evaluation of areas, volumes of revolution, force, and work; fundamental formulas and various techniques of integration applied to both single variable and multivariable functions; tracing of functions of two variables.

##### DIFFERENTIAL EQUATIONS

Differentiation and integration in solving first order, first-degree differential equations, and linear differential equations of order n; Laplace transforms in solving differential equations.

##### PROBABILITY AND STATISTICS

Basic principles of statistics; presentation and analysis of data; averages, median, mode; deviations; probability distributions; normal curves and applications; regression analysis and correlation; application to engineering problems.

##### GENERAL CHEMISTRY

Basic concepts of matter and its classification; mass relationships in chemical reactions; properties of gases, liquids, and solids; concepts of thermochemistry; the quantum theory and electronic behavior; periodic relationship of elements in the periodic table; intramolecular forces; and solutions.

##### PHYSICS 1

Vectors; kinematics; dynamics; work, energy, and power; impulse and momentum;

Rotation; dynamics of rotation; elasticity; and oscillation.

##### PHYSICS 2

Fluids; thermal expansion, thermal stress; heat transfer; calorimetry; waves; electrostatics; electricity; magnetism; optics; image formation by plane and curved mirrors; and image formation by thin lenses.

##### ENGINEERING DRAWING

Practices and techniques of graphical communication; application of drafting instruments, lettering scale, and units of measure; descriptive geometry; orthographic projections; auxiliary views; dimensioning; sectional views; pictorial drawings; requirements of engineering working drawings; and assembly and exploded detailed drawings.

##### COMPUTER FUNDAMENTALS AND PROGRAMMING

Basic information technology concepts; fundamentals of algorithm development; high-level language and programming applications; computer solutions of engineering problems.

##### COMPUTER-AIDED DRAFTING

Concepts of computer-aided drafting (CAD); introduction to the CAD environment; terminologies; and the general operating procedures and techniques in entering and executing basic CAD commands.

##### STATICS OF RIGID BODIES

Force systems; structure analyses; friction; centroids and centers of gravity; and moments of inertia.

##### DYNAMICS OF RIGID BODIES

Kinetics and kinematics of a particle; kinetics and kinematics of rigid bodies; work-energy method; and impulse and momentum.

##### MECHANICS OF DEFORMABLE BODIES

Axial stress and strain; stresses for torsion and bending; combined stresses; beam deflections; indeterminate beams; and elastic instability.

##### ENGINEERING ECONOMY

Concepts of the time value of money and equivalence; basic economy study methods; decisions under certainty; decisions recognizing risk; and decisions admitting uncertainty.

##### ENGINEERING MANAGEMENT

Decision-making; the functions of management; managing production and service operations; managing the marketing function; and managing the finance function.

##### ENVIRONMENTAL ENGINEERING

Ecological framework of sustainable development; pollution environments: water, air, and solid; waste treatment processes, disposal, and management; government legislation, rules, and regulation related to the environment and waste management; and environmental management system.

##### SAFETY MANAGEMENT

Evolution of safety management; safety terminology; safety programs adopted by high-risk industries; hazards in the construction, manufacturing, gas and power plants, and other engineering industries and how to prevent or mitigate them; techniques in hazard identification and analysis in workplaces; off-the-job safety; disaster prevention and mitigation; and incident investigation.

##### ADVANCED ENGINEERING MATHEMATICS FOR EE

A study of selected topics in mathematics and their applications in advanced courses in engineering and other allied sciences. It covers the study of Complex numbers and complex variables, Laplace and Inverse Laplace Transforms, Power series, Fourier series, Fourier Transforms, transforms power series solution of ordinary differential equations, and partial differential equations.

##### BASIC THERMODYNAMICS

A course dealing with the thermodynamic properties of pure substances, ideal and real gases, and the study and application of the laws of thermodynamics in the analysis of processes and cycles. It includes an introduction to vapor and gas cycles.

##### LOGIC CIRCUITS AND SWITCHING THEORY

Review of number systems, coding, and Boolean algebra; inputs and outputs; gates and gating networks; combinational circuits; standard form; minimization; sequential circuits; state and machine equivalence; asynchronous sequential circuits; race conditions; algorithmic state machines; design of digital subsystems.

##### ELECTROMAGNETICS

Electric and magnetic fields, resistive, dielectric, and magnetic materials, coupled circuits, magnetic circuits and fields, time-varying electromagnetic fields, and Maxwell’s equations.

##### MICROPROCESSOR SYSTEMS

The course covers concepts involving microprocessor/microcontroller systems architecture/organization including microprocessor/microcontroller programming, interfacing techniques, memory systems, and bus standards. In the laboratory, the students will be involved with experiments using microcontrollers and the use microprocessor/ microcontroller development systems and other tools. Experiment topics include assembly language programming topics, interfacing with input and output devices, data transfer between microcontroller-based circuits and the PC via the serial port and parallel port.

##### PRINCIPLES OF COMMUNICATIONS

Bandwidth; filters; linear modulation; angle modulation; phase-locked loop; pulse modulation; multiplexing techniques; noise analysis; radio transmitters and receivers, Introduction to Data Communication.

##### CONTROL SYSTEM ANALYSIS

This course deals with the time and frequency response of feedback control systems. The topics covered include time response of first-order and second-order systems, modeling, transfer functions, pole-zero map, stability analysis, root locus, bode plots, compensators, PID controllers, and introduction to state-space techniques.

##### ELECTRONIC CIRCUITS AND DEVICES

Introduction to quantum mechanics of solid-state electronics; diode and transistor characteristics and models (BJT and FET); diode circuit analysis and applications; transistor biasing; small-signal analysis; large signal analysis; transistor amplifiers; Boolean logic; transistor switch.

##### ELECTRONIC CIRCUITS ANALYSIS AND DESIGN

High-frequency transistor models; analysis of transistor circuits; multi-stage amplifier, feedback, differential amplifiers, and operational amplifiers; integrated circuit families (RTL, DTL, TTL, ECL, MOS)

##### INDUSTRIAL ELECTRONICS

Theory and operating characteristics of electronic devices and control circuits for industrial processes; industrial control applications; electronics instrumentation; transducers; data acquisition system, power supply, and voltage regulator.

##### MECHANICS OF FLUID

It covers properties of fluid, pressure intensity, static pressure, and relative equilibrium of liquids, kinematics of flow and fluid dynamics flow through orifices, nozzles, venturi meters, weirs, and flow meters.

##### FUNDAMENTALS OF MATERIALS SCIENCE AND ENGINEERING

Structure and composition of materials (metals, polymers, ceramics, and composites). Processing, properties, and behavior in service environments

##### INFORMATION TECHNOLOGY

A discussion to the field of Information Technology that focuses on software development, data communications computer networking, databases, internet, and web technologies.

##### EE LAWS, CONTRACTS, AND ETHICS

This course deals with the study of existing laws, codes, ethics, and standards in the practice of the electrical engineering profession.

##### ELECTRICAL TRANSMISSION AND DISTRIBUTION SYSTEMS

This course deals with the study and design of primary and secondary distribution networks, load characteristics, voltage regulation, metering techniques and systems, and protection of distribution systems.

##### ELECTRICAL SYSTEM DESIGN

This course deals with the study of electrical system design, installation, and cost estimation for commercial and industrial establishments, guided by the provisions of the Philippine Electrical Code (PEC) and other relevant laws and standards.

##### INSTRUMENTATION AND CONTROL

Control and Testing; Electromechanical, analog, and digital measuring and testing instruments; R, L and C measurements: calibration; graphic and waveform analyzing instruments; and detectors for the measurements of process variables; analysis of performance characteristics of control systems, electronics, magnetic, hydraulic and mechanical control

##### ELECTRICAL CIRCUITS I (LECTURE)

Covers the basic concepts and fundamental laws of electrical circuit theory; analysis and applications of series, parallel, and series-parallel resistive circuits; mesh and nodal analysis; network theorems; characteristics of inductors and capacitors; analysis of RL, RC, and RLC circuits with DC excitation

##### ELECTRICAL CIRCUITS I (LABORATORY)

##### A laboratory course to accompany Electrical Circuits I (lecture).

##### ELECTRICAL CIRCUITS II (LECTURE)

Covers the steady-state frequency domain analysis of RLC circuits driven by sinusoidal voltage/current source(s); impedance bridge circuits; application of mesh/nodal analysis and network theorems in AC circuit analysis; the concept of power and power factor correction in AC circuits; resonant and tuned circuits; two-port network analysis; analysis of dynamic circuits with excitation

##### ELECTRICAL CIRCUITS II (LABORATORY)

A laboratory course to accompany Electrical Circuits II (Lecture).

##### ELECTRICAL CIRCUITS III (LECTURE)

Covers the analysis of balanced three-phase systems, with balanced and unbalanced loading; analysis of circuits with magnetically-coupled coils; symmetrical components; per unit calculations

##### AC APPARATUS AND DEVICES (LECTURE)

Covers theory, the principle of operation and applications of single-phase transformers, parallel operation of transformers, autotransformers, three-phase transformers, instrument transformers, circuit breakers, power relays, and other selected equipment and devices currently used in the field as basic requirements of an electrical system.

##### ELECTRICAL EQUIPMENT OPERATION & MAINTENANCE

Covers the principle of operation, functions, characteristics, and applications of different electrical equipment and devices; also covers the design, installation and troubleshooting, automation, and control of different kinds of industrial motors.

##### AC MACHINERY (LECTURE)

Covers theory, the principle of operation, engineering aspects, and applications of three-phase alternators, three-phase induction motors, synchronous motors and single-phase motors

##### AC MACHINERY – (LABORATORY)

Covers experiments to demonstrate the operating characteristics of alternators, induction motors, synchronous motors, and other types of motors; also covers the simulation of the principle of operation and the characteristics of electrical machines based on industrial applications

##### DC MACHINERY (LECTURE)

Covers the basic principles of electromechanical energy conversion, generalized machine model, and the operating characteristics of DC machines and synchronous machines.

##### POWER PLANT ENGINEERING

Includes Load Graphics, types of power plants, power plant operation, and protection, interconnections, the economics of electric service, and arrangement of equipment for modern plants.

##### POWER SYSTEM ANALYSIS AND DESIGN

The basic structure of power systems, recent trends, and innovations in power systems, complex power, per-unit quantities, transmission line parameters, network modeling and calculations, load flow studies, short circuit calculations, use of computer software for simulation

##### ELECTRICAL ENGINEERING SAFETY

Deals with the industrial accident prevention and safety organization, accident analysis, selection and application of remedy/corrective actions, industrial health and environmental concerns, first-aid, and CPR.

##### ILLUMINATION ENGINEERING DESIGN

This course deals with the study, design, application, and maintenance, the cost estimate of electrical system design, and the use of energy-efficient lighting systems in residential, commercial, and industrial establishments.

##### NUMERICAL METHODS WITH COMPUTER APPLICATION

This course deals with the study of direct and interactive numerical methods in engineering, determination of error bounds in calculations, computation of series expansions, roots of algebraic and transcendental equations, numerical differentiation and integration, the solution to simultaneous linear and non-linear equations, function approximation, and interpolation, differential equations, optimization, and their applications

##### ADVANCED ENGINEERING MATHEMATICS (FOR ECE)

A study of selected topics in mathematics and their applications in advanced courses in engineering and other allied sciences. It covers the study of Complex numbers and complex variables, Laplace and Inverse Laplace Transforms, Power series, Fourier series, Fourier Transforms, z-transforms, power series solution of ordinary differential equations, and partial differential equations.

DISCRETE MATHEMATICS

This course deals with logic, sets, proofs, growth of functions, theory of numbers, counting techniques, trees, and graph theory.

BASIC THERMODYNAMICS

A course dealing with the thermodynamic properties of pure substances, ideal and real gases, and the study and application of the laws of thermodynamics in the analysis of processes and cycles. It includes an introduction to vapor and gas cycles.

FUNDAMENTALS OF MATERIALS SCIENCE AND ENGINEERING

Structure and composition of materials (metals, polymers, ceramics, and composites). Processing, properties, and behavior in service environments.`Contracts; warranties; liabilities; patents; bids; insurance; other topics on the legal and ethical positions of the professional engineer.

CIRCUITS 1

Fundamental relationships in circuit theory, mesh and node equations; resistive networks, network theorems; solutions of network problems using Laplace transform; transient analysis; methods of circuit analysis.

CIRCUITS 2

Complex algebra and phasors; simple AC circuits, impedance, and admittance; mesh and node analysis for AC circuits; AC network theorems; power in AC circuits; resonance; three-phase circuits; transformers; two-port network parameters and transfer function.

ELECTRONIC DEVICES AND CIRCUITS

Introduction to quantum mechanics of solid-state electronics; diode and transistor characteristics and models (BJT and FET); diode circuit analysis and applications; transistor biasing; small-signal analysis; large signal analysis; transistor amplifiers; Boolean logic; transistor switch.

ELECTRONIC CIRCUITS ANALYSIS AND DESIGN

High-frequency transistor models; analysis of transistor circuits; multi-stage amplifier, feedback, differential amplifiers, and operational amplifiers; integrated circuit families (RTL, DTL, TTL, ECL, MOS)

INDUSTRIAL ELECTRONICS

Theory and operating characteristics of electronic devices and control circuits for industrial processes; industrial control applications; electronic instrumentation; transducers; data acquisition system, power supply and voltage regulator

VECTOR ANALYST

his course deals with vector algebra, vector calculus, vector analysis, and theirApplications

ELECTROMAGNETICS

This course deals with electric and magnetic fields, resistive, dielectric, and magnetic materials, coupled circuits, magnetic circuits and fields, time-varying electromagnetic fields, and Maxwell’s equations.

SIGNALS SPECTRA, AND SIGNAL PROCESSING

Fourier transform; z transform; convolution; FIR filters; IIR filters; random signal analysis; correlation functions; DFT; FFT; spectral analysis; applications of signal processing to speech, image, etc.

ENERGY CONVERSION

Principles of energy conversion and transducers: electromechanical, photoelectric, photovoltaic, thermoelectric, piezoelectric; hall-effect; reed switch; electrochemical, etc; generators, transformers; dynamic analysis, and fuel cells.

PRINCIPLES OF COMMUNICATIONS

Bandwidth; filters; linear modulation; angle modulation; phase-locked loop; pulse modulation; multiplexing techniques; noise analysis; radio transmitters and receivers.

LOGIC CIRCUITS AND SWITCHING THEORY

Review of number systems, coding, and Boolean algebra; inputs and outputs; gates and gating networks; combinational circuits; standard form; minimization; sequential circuits; state and machine equivalence; asynchronous sequential circuits; race conditions; algorithmic state machines; design of digital subsystems.

NUMERICAL METHODS

Numerical Methods deals with the study of direct and interactive numerical methods in engineering, determination of error bounds in calculations, computation of series expansions, roots of algebraic and transcend entail equations, numerical differentiation and integration, the solution to simultaneous linear and non-linear equations, function approximation and interpolation, differential equations, optimization, and their applications.

TRANSMISSION MEDIA AND ANTENNA SYSTEMS

Transmission media; radio wave propagation wire and cable transmission systems; fiber-optic transmission system; transmission lines and antenna systems.

MICROPROCESSOR SYSTEMS

1. The course covers concepts involving microprocessor/ microcontroller systems architecture/organization including microprocessor/microcontroller programming, interfacing techniques, memory systems, and bus standards.2. In the laboratory, the students will be involved with experiments using microcontrollers and the use microprocessor/ microcontroller development systems and other tools. Experiment topics include assembly language programming topics, interfacing with input and output devices, data transfer between microcontroller-based circuits and the PC via the serial port and parallel port.

FEEDBACK AND CONTROL SYSTEMS

This course deals with the time and frequency response of feedback control systems. The topics covered include time response of first-order and second-order systems, modeling, transfer functions, pole-zero map, stability analysis, root locus, bode plots, compensators, PID controllers, and introduction to state-space techniques.

DIGITAL COMMUNICATIONS

Random variables, bit error rate; matched filter; Digital modulation techniques; ASK, FSK, QAM, PSK/QPSK, CDMA, and W-CDMA systems; signal space; generalized orthonormal signals; information measures-entropy; channel capacity; efficient encoding; error-correcting codes information theory; data compression; coding theory.

DATA COMMUNICATIONS

Data communication systems; terminals, modems; terminal control units; multiplexers; concentrators; front-end processors; common carrier services; data communication system design; computer network models; TCP/IP principles; LAN; WAN; sample case studies

##### MATH1-COLLEGE ALGEBRA

Algebraic expressions and equations; solution sets of algebraic equations in one variable: linear, quadratic, polynomial of degree *f*ractional, radical equations, quadratic in form, exponential and logarithmic equations; decomposition of fractions into partial fractions; solution sets of systems of linear equations involving up to three variables.

##### MATH2-PLANE AND SPHERICAL TRIGONOMETRY

Trigonometric functions; identities and equations; solutions of triangles; law of sines; law of cosines; inverse trigonometric functions; spherical trigonometry

##### MATH3-ADVANCED ALGEBRA

Matrices and determinants; arithmetic and geometric series; solution sets of different types of inequalities and systems involving quadratics; solution of linear equations using determinants and matrices.

##### MATH3-ANALYTIC GEOMETRY

Equations of lines and conic sections; curve tracing in both rectangular and polar coordinates in two-dimensional space.

##### MATH4-SOLID MENSURATION

Concept of lines and planes; Cavalieri’s and Volume theorems; formulas for areas of plane figures, volumes for solids; volumes and surfaces areas for spheres, pyramids, and cones; zone, sector, and segment of a sphere; theorems of Pappus.

##### MATH5-DIFFERENTIAL CALCULUS

Basic concepts of calculus such as limits, continuity and differentiability of functions; differentiation of algebraic and transcendental functions involving one or more variables; applications of differential calculus to problems on optimization, rates of change, related rates, tangents and normal, and approximations; partial differentiation and transcendental curve tracing.

##### MATH6-INTEGRAL CALCULUS

Concept of integration and its application to physical problems such as evaluation of areas, volumes of revolution, force, and work; fundamental formulas and various techniques of integration applied to both single variable and multi-variable functions; tracing of functions of two variables.

##### MATH7-DIFFERENTIAL EQUATIONS

Differentiation and integration in solving first order, first-degree differential equations, and linear differential equations of order *n*; Laplace transforms in solving differential equations.

##### STAT1-PROBABILITY AND STATISTICS

Basic principles of statistics; presentation and analysis of data; averages, median, mode; deviations; probability distributions; normal curves and applications; regression analysis and correlation; application to engineering problems.

##### CHEM1-GENERAL CHEMISTRY

Basic concepts of matter and its classification; mass relationships in chemical reactions; properties of gases, liquids, and solids; concepts of thermochemistry; the quantum theory and electronic behavior; periodic relationship of elements in the periodic table; intramolecular forces; and solutions.

##### PHY1-PHYSICS 1

Vectors; kinematics; dynamics; work, energy, and power; impulse and momentum; rotation; dynamics of rotation; elasticity; and oscillation.

##### PHY2-PHYSICS 2

Fluids; thermal expansion, thermal stress; heat transfer; calorimetry; waves; electrostatics; electricity; magnetism; optics; image formation by plane and curved mirrors; and image formation by thin lenses.

##### DRAW1-ENGINEERING DRAWING

Practices and techniques of graphical communication; application of drafting instruments, lettering scale, and units of measure; descriptive geometry; orthographic projections; auxiliary views; dimensioning; sectional views; pictorial drawings; requirements of engineering working drawings; and assembly and exploded detailed drawings.

##### COMP1-COMPUTER FUNDAMENTALS AND PROGRAMMING

Basic information technology concepts; fundamentals of algorithm development; high-level language and programming applications; computer solutions of engineering problems.

##### COMP2-COMPUTER-AIDED DRAFTING

Concepts of computer-aided drafting (CAD); introduction to the CAD environment; terminologies; and the general operating procedures and techniques in entering and executing basic CAD commands.

##### ME311-STATICS OF RIGID BODIES

Force systems; structure analyses; friction; centroids and centers of gravity; and moments of inertia.

##### ME321-DYNAMICS OF RIGID BODIES

Kinetics and kinematics of a particle; kinetics and kinematics of rigid bodies; work-energy method; and impulse and momentum.

##### ME322-MECHANICS OF DEFORMABLE BODIES

Axial stress and strain; stresses for torsion and bending; combined stresses; beam deflections; indeterminate beams; and elastic instability.

##### ME421-ENGINEERING ECONOMY

Concepts of the time value of money and equivalence; basic economy study methods; decisions under certainty; decisions recognizing risk; and decisions admitting uncertainty.

##### ME522-ENGINEERING MANAGEMENT

Decision-making; the functions of management; managing production and service operations; managing the marketing function; and managing the finance function.

##### ME312-ENVIRONMENTAL ENGINEERING

Ecological framework of sustainable development; pollution environments: water, air, and solid; waste treatment processes, disposal, and management; government legislation, rules, and regulation related to the environment and waste management; and environmental management system.

##### ME323-SAFETY MANAGEMENT

Evolution of safety management; safety terminology; safety programs adopted by high-risk industries; hazards in the construction, manufacturing, gas and power plants, and other engineering industries and how to prevent or mitigate them; techniques in hazard identification and analysis in workplaces; off-the-job safety; disaster prevention and mitigation; and incident investigation.

##### EE221-BASIC ELECTRICAL ENGINEERING

This course covers the fundamentals of both DC and AC circuits intended for non-EE major students. It covers the principles, basic laws, and theorems used in analyzing electrical circuits in both direct current and alternating current conditions.

##### BASIC ELECTRONICS

This Course discusses the construction, operation, and characteristics of basic electronics devices such as PN junction diode, light-emitting diode, Zener diode, Bipolar Junction Transistor, and Field Effect Transistor. Diode circuit applications such as clipper, clamper, and switching diode circuits will be a part of the lecture. Operation of a DC-regulated power supply, as well as analysis of BJT and FET amplifier circuit, will be tackled. This course also discusses the operation and characteristics of operational amplifiers

##### EE411-DC AND AC MACHINERY

The course deals with performance characteristics and operation including losses and efficiencies of DC and AC machines such as alternators, induction/synchronous motors, synchronous converters, and transformers. It includes demonstrations and laboratory experiments.

##### MECH111-ORIENTATION TO ME

To provide information in the field of Mechanical Engineering

##### MECH421-ADVANCED ENGINEERING MATHEMATICS FOR ME

A study of selected topics in mathematics and their applications in advanced courses in engineering and other allied sciences. It covers the study of Complex Numbers, Laplace and Inverse Laplace Transforms, Power series, Fourier series, Matrices and Determinants, Vector Analysis, and Numerical Methods.

##### MECH425-METHODS OF RESEARCH FOR MECHANICAL ENGINEERING

This course covers the study of the methodologies used in conducting engineering research. It includes the types and application of research, characteristics of good research, research design, research instrument, and data gathering procedures. It also deals with the study of writing a research proposal and various formats.

##### MECH323-FLUID MECHANICS

The course deals with the nature and physical properties of fluids as well as the identification and measurement of fluid properties. It emphasizes the application of conservation laws on mass; energy and momentum to fluid systems either in compressible or compressible flow and in viscid or viscous flow as well as head loss calculation on pipes and fittings.

##### ME313-MACHINE ELEMENTS 1 (Kinematics and Dynamics of Machines)

The course deals with the study of mechanisms disregarding the forces and Energies that cause motion. It emphasizes the analytical and graphical study of displacement, velocity, and acceleration.

##### ME324-MACHINE ELEMENTS 2

A study of the elements of mechanism such as gears, train, rolling bodies, belt, and pulleys, cams, and follower

##### ME411-MATERIALS ENGINEERING

The course deals with the properties of engineering materials including mechanical acoustical, electrical, magnetic, chemical, optical, and thermal properties; laboratory experiments using equipment include; tension, compression, bending shear, torsion, and impact tests.

##### MECH312-THERMODYNAMICS 1

A course dealing with the thermodynamic properties of pure substances, ideal and real gases, and the study and application of the laws of thermodynamics in the analysis of processes and cycles. It includes an introduction to vapor and gas cycles.

##### MECH321-THERMODYNAMICS 2

This course is aimed to further enhance the students’ knowledge regarding the principles of Thermodynamics by using these principles in a practical application specifically in the field of power generation. This includes the study of real gases, properties of gas and vapor mixtures, and introduction to reactive systems.

##### MECH423-COMBUSTION ENGINEERING

The course deals with principles involved in combustion, carburetion, and fuel injection; fundamentals and basic principles of combustion processes, compression and combustion charts, fuels, (manifolds) engine components, engine performance, and combustion engine design.

##### MECH411-HEAT TRANSFER

The course deals with the different modes of heat and mass transfer; laws governing conduction, convection, and radiation, and its application to the design of common heat exchangers such as condensers. Cooling coils and evaporators; and the environmental impact of their operation.

##### MECH413-ME LABORATORY 1

The course involves studying and using devices and instruments used to measure pressure, temperature level, flow, Speed, weight, area, volume, viscosity, steam quality, and combustion products. It also includes the study and analysis of fuels and lubricants.

##### MECH422-ME Laboratory 2

The course involves the study and test of mechanical engineering equipment and machinery such as steam generator, steam turbine, heat exchangers, internal and external combustion engines, pumps, fans, blowers, and compressors

##### MECH513-INDUSTRIAL PROCESSES

A course dealing with the study of industrial and manufacturing processes and the equipment involved in the processes.

##### ME511-SAFETY ENGINEERING FOR ME

A course that deals with the study of industrial safety and health. It includes risk mitigation processes and components from hazards and risk identification, evaluation, and control.

##### MECH311-WORKSHOP THEORY AND PRACTICE

The course deals with the basic principles of machine shop practices. It includes workshop safety and organization; simple workshop measuring instruments, hand tools, fitting bench work, bench drill, and bench grinder; sheet metal working; principles of welding processes; welding metallurgy; joining processes; testing and inspection of welds; foundry and metal casting.

##### MECH322-MACHINE SHOP THEORY

The course deals with the use and operation of machines such as lathes, shapers, planers, drilling and boring machines, milling machine, cutters, grinding machines, machine tools, and accessories. It covers technological advances in metalworking and innovations in a machine shop.

##### EE511-INSTRUMENTATION AND CONTROL ENGINEERING

The course introduces the basic concepts of instrumentation and process controls as well as important applications of feedback control systems with an emphasis on analysis as well as design techniques.

##### MECH421-FLUID MACHINERY

The course is a comprehensive study of the principles and theories in the proper operation, selection, and application of the most commonly used fluid machinery such as pumps, fans, blowers, compressors, and turbines.

##### MECH424-REFRIGERATION SYSTEMS

The course is designed to provide a thorough foundation of the thermodynamic principles and components of mechanical refrigeration systems; cycles and associated equipment, and the effect of their operation on the environment.

##### MECH511-AIR CONDITIONING AND VENTILATION SYSTEMS

AIR CONDITIONING THEORY AND DESIGN. The course deals with Psychometric properties of air; factors affecting human comfort; air distribution and basic duct design, drying, heating, and ventilation; cooling load calculations; complete design of an air-conditioning system and its components.

##### ME512-VIBRATION ENGINEERING

This course is intended to introduce the students to the fundamental concepts of vibration as it affects the operation and performance of machine components. It involves modeling mechanical systems, derivation of the differential equations for such systems, and varying solutions (responses) based on different excitation. Emphases will be on analysis, design, measurement, damping, and computational aspects. The computer as a computational tool will also be utilized.

##### ME412-MACHINE DESIGN 1

The course deals with various mechanical properties of engineering materials in place of the determination of design factors and design stresses. It includes the analyses of simple, variable, and combined stresses applied to different mechanical elements such as shafts, mechanical springs.

##### ME422-MACHINE DESIGN 2

The course covers the design of various mechanical elements such as brakes and clutches, bearings, flexible transmitting elements, gears, flywheels. It also includes the study of welding design.

##### MECH512-ME LABORATORY 3

The course deals with the performance analysis and evaluation of refrigeration, air-conditioning, and ventilation systems and power plants.

##### MECH521-INDUSTRIAL PLANT ENGINEERING

A study of mechanical engineering theories, equipment, and systems needed in the operation of an industrial/manufacturing plant.

##### MECH522-POWER PLANT ENGINEERING

Study of the fundamental concepts in the design and installation of typical power plants such as steam power plant, diesel-electric plant, geothermal power plant as well as other generating plants using non-conventional sources of energy.

##### ME521-ME LAW, ETHICS, CODES, AND STANDARDS

The course deals with the study of the Mechanical Engineering law, code of ethics, ethical theories, and ethical issues in the practice of engineering. Familiarization with the technical codes and standards are included

##### MECH514-PLANT VISIT OR OJT

The study includes visits and/or exposure to power plants and industrial/manufacturing plants

##### RES1-ME PROJECT STUDY 1

The first phase of the mechanical engineering project study involving writing and defense of the project proposal

##### RES2-ME PROJECT STUDY 2

The second phase of the mechanical engineering project study includes the completion and final defense of the approved project.

### Electives

##### ME ELEC1-MECHATRONICS

Introduction to mechanical system interfacing; combinational digital logic; industrial electronic components; industrial sensors; simple computer structure; low-level programming techniques; embedded control computers; micro controller; stepping motors; DC motors; analog/digital conversion; position and velocity measurement; amplifiers; projects related to mechatronics.

##### ME ELEC3-CONTROL SYSTEMS ENGINEERING

Introduction to control system; mathematical models of systems; state-space description; dynamics simulation; feedback control system characteristics; the performance of feedback control systems; the stability of linear feedback systems; essential principles of feedback, the root-locus method; frequency-domain, time-domain analysis of control systems; the design and compensation of feedback control systems.

##### ME ELEC4-INDUSTRIAL AUTOMATION & CONTROL

Review of basic control system; industrial control component: pneumatic, electric, electronic and fluid device; analysis and design of the complete control systems; special control applications: boiler control, air condition control, flight control, introduction to direct digital control and supervisory control.