E ELECTRICAL ENGINEERING
Basic principles of signals and systems. Analysis of techniques in signals and continuous system techniques through time domains. Analysis of techniques in signals and continuous system techniques through frequency domain. Signal modulation principles. Introduction to analog-filter design. Textbook: Rodger E. Ziemer, Signals and Systems: Continous and Discrete, MacMillan, tercera edición, 1993.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00002. DIGITAL SIGNALS PROCESSING SYSTEMS
Study of A/D conversion principles including sampling, quantification, codification and calculation of signal to noise relation. Analysis of discrete signals and systems according to time. Analysis of discrete signals and systems according to frequency. Study of discrete system analysis and Z-transformations and applications. Introduction to digital filter design. Textbook: Rodger E. Zeimer, Signals and Systems: Continouos and Discrete, MacMillan, 3rd edition, 1993.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Analyzing linear and non-linear magnetic circuits. Calculating losses in ferromagnetic nucle. This course surveys the characteristics of an ideal transformer. Knowledge and application of the equivalent circuit in a transformer and in three-phase transformers. Familiarization with induction motors and knowledge and application of equivalent circuits in induction motors. Calculate torque- the principle velocity of an induction motor. Textbook: P.C. Sen, Principles of Electric Machines and Power Electronics, John Wiley and Sons, 1989.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00004. ELECTIC ENERGY CONTROLLERS
Study of synchronic machinery of cylindrical runner systems. Knowledge and application of an equivalent circuit of a synchronic machine. Principal operational characteristics of a synchronic machine. Study of direct current motors and understanding different connections of direct current motors. Development of equivalent circuits in direct current motors. Characteristics of torque- velocity of direct current motors. Familiarization with direct current motor controls. Description of power semiconductors. Analysis of rectifiers with diodes and controlled rectifiers. Study voltage controls in alternate currents. Understanding operational systems of direct current converters and velocity controls with solid state equipment. Textbook: P.C. Sen, Principles of Electric Machines and Power Electronics, John Wiley and Sons, 1989.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00005 . PRINCIPLES OF ELECTRIC AND ELECTRONIC ENERGY
energy "To know and analyze the basic principles of energy. Obtaining and transforming energy. To study the different kinds of energy, electrical, solar and kinesthetic. Basic knowledge of electronics and its application to the design of basic products such as house appliances, toys and training equipment."
E00006. ELECTROMAGNETIC ACTUATORS
"To know the basic principles of electromagnetic energy conversion. To analyze the behavior of the electromagnetic actors. To study the operation principles of electric engines. Magnetic circuits. Electric transformers Electromagnetic actor principles. Direct current engines. Induction engines. Synchronic engines. Textbook: Slemon, Gordon.(1992) Electric Machines and Drives. Addison Wesley."
LANGUAGE OF INSTRUCTION: SPANISH
E00007. INSUSTRIAL ELECTRONIC LABORATORY
"Electronic conditioning circuit design, signal generators and power interphases.
Construction of solid state converters
for the electric energy transformation and control. Analysis, design and optimization
of the pair regulation control and
the control system speed of electric engines. Operation of the engine control
centers of CD and CA (DC/AC drives)
Power semiconductor devices. Electronic conditioning. Solid state converters,
electric energy quality; Power factor and
harmonic content, pair control and electric engine speed. Control center engine
CD/CA. Textbook: Vithayathil, Joseph.
(1995) Power Electronics: Principles and applications. McGraw Hill."
E00811. INTRODUCTION TO ENGINEERING
Familiarization with the organization of the technological system of Monterrey. Norms, policies and principles for undergraduate students. Carreer profiles and programs of study. Development, importance and future of a carreer in the field. Job market and areas of opportunity. General methodology for engineering projects. Textbook: Legislación Académica para los Alumnos de las Carreras Profesionales, ITESM, 1994.
CAMPUS: VER, CHIS, CHIH, CCM, C.JUA, OBRE, COL, CEM, HID, IRAP, LAG, LEO, MAZ, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Rationalized systems of MKS units. Definitions of elements of a circuit. Application of experimental circuit laws and resolution of simple circuits. Nodes and mesh equations, superposition and Thevenin theorem. Familiarization of inductance and capacitance in simple circuits. RL and RC circuits without independent sources. Unitary steps of forced function. RLC circuits with and without constant sources. Textbook: Williams H. Hayt and Jack E. Kemmerly, Engineering Circuits Analysis, McGraw-Hill, Inc., 5th edition, 1993.
CAMPUS: CCM, CEM, GDA, LAG, MTY, CVC, QRO, TOL.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Study of sinusoidal forcing function in electrical circuits. Concept of phasor. Response of stable sinusoidal state of circuits using phasors. Average force, reactive force, apparent force, complex force and effective circuit values. Poly-phase circuits, complex frequencies and effective circuit values. Poly-phase circuits, response to frequencies, and magnetically switched circuits. Textbook: Williams H. Hayt and Jack E. Kemmerly, Engineering Circuits Analysis, McGraw-Hill, Inc., 5th edition, 1993.
CAMPUS: CCM, CEM, GDA, LAG, MTY, CVC, QRO, TOL.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Numerical codes and systems. Basic sluices for the design of combinational systems. Principles of Boolean algebra and map methodology for minimizing functions. Bistable, monostable and astable multivibrators. Designing simple sequential systems. Operational principles of commercial, sequential and combinational functional blocks. Implementation of digital systems analysis of medium complexity. Textbook: Ronald J. Tocci, Sistemas Digitales, Principios y Aplicaciones, Prentice Hall Hispanoamericana, quinta edición, 1993.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Memory devices, elements and circuit design. Sequential circuits for digital control systems. Commercial programmable logic. Algorithms of basic arithmetic functions and system implementation. Operational principles and important parameters of the most common logical families. Textbooks: John F. Wakerly, Diseño digital, principios y prácticas, Prentice Hall Hispanoamericana, Primera edición, 1992. Ronald J. Tocci, Sistemas Digitales, Principios y Aplicaciones, Prentice Hall Hispanoamericana, quinta edición, 1993.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00837. DIGITAL SYSTEMS
This course studies the basic concepts of digital systems and procedures of design of digital combinational and sequential systems. The course also covers the study and application of dispositives of memory and dispositives of programmable logic. The student will develop the ability to design and implant digital systems for everyday use with commercial components and computer simulation packages.
LANGUAGE OF INSTRUCTION: SPANISH
E00851. ENERGY CONVERSION I
"To analyze magnetic linear and non-linear circuits. To calculate the
losses in ferromagnetic nucleus. To describe the
characteristics of an ideal transformer. To study three-phase transformers.
To describe an induction engine. To study the
operation principles of step engines. Textbook: Sen, P.C.(1989) Principles of
electric machines and power electronics. John Wiley and Sons."
LANGUAGE OF INSTRUCTION: SPANISH
E00852. ELECTROMECHANICAL ENERGY CONVERSION II
"To study the synchronic engine of a cylindrical rotor to know and apply the equivalent circuit of a synchronic engine. To know the important operation characteristics of a synchronic engine. To study the engine of direct current. To know the different engine c onnections to direct current. Characteristics of pair-speed of direct current engines. To know the speed controls of direct current engines. To describe the power semiconductors. To analyze the rectifiers with diodes and controlled rectifiers. To study the voltage controls of alternate current. To understand the operation of direct current converters to direct current. To describe the speed controls with solid state equipment. Textbook: Sen, P.C. (1989). Principles of electric machines and power electronics. John Wiley and Sons."
LANGUAGE OF INSTRUCTION: SPANISH
E00853. ELECTROMAGNETIC FIELDS
Study of an electromagnetic model: intensity and density of electrical and magnetic fields. Vectorial analysis: arithmetics and calculus using vectorial fields. Electrostatic fields: Coulomb's Law, Gauss' Law and electrostatic energy. Conductions and dielectric materials. Electrostatic problems with boundary value: Poisson and Laplace equations and unity theorem. Stable electric currents: field of current density field and current continuity equation. Magnetostatic fields: Ampere and Biot-Savart laws, magnetic permeability, magnetic circuits, magnetic force, inductance and magnetic energy. Changing fields in time, law of Faraday and 4 Maxwell equations. Textbook: David K. Cheng, Field and Wave Electromagnetics, Addison-Wesley, segunda edición, 1989.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Study of charges and current movements in semiconductors. Circuits with diodes and regulator circuits with zener diodes. Bipolar transistors and field effect transistors. Electronic circuits with small signals and medium wave lengths. Amplifying circuits with various transistors at medium wave-length frequencies. Understanding frequency of amplifiers with bipolar transistors and field effect transistors. Computerized simulators. Textbook: Robert Boytlestand and Louis Nashelsky, Electrónica: Teoría de Circuitos, Prentice Hall Hispanoamericana, quinta edición.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Principles of operations and applications of rectifier diodes and regulator diodes. Power sources in linear regulators. Bipolar transistor and transistors of field effects. Special applications of semiconductor devices. Introduction to computer design and simulation of semiconductor devices and analogic circuits. Textbooks: Sedra and Smith, Microelectronic Circuits, Saunders College Publishing, 1991. Boylestad and Nashelsky, Electronic Devices and Circuit Theory, Prentice Hall, 1992.
CAMPUS: CCM, CEM, GDA, LAG, MTY, CVC, QRO, TOL.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Understanding small-signal models for bipolar transistors and field-effect transistors. Basic configurations for amplifiers. Type A, B, AB, and D amplifiers. Analysis of amplifier frequency responses. Negative feedback in amplifiers. Textbooks: Sedra and Smith, Microelectronic Circuits, Saunders College Publishing, 1991. Boylestad and Nashelsky, Electronic Devices and Circuit Theory, Prentice Hall, 1992.
CAMPUS: CCM, CEM, GDA, LAG, MTY, CVC, QRO, TOL.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00857. MICROPROCESSORS AND PERIPHERALS
Study of typical architecture and operation of microprocessors and microcontrollers. Understanding instructions, language programming in models and assemblers. Interruptions and use and functions of common peripherals such as temporizators/counters and parallel/serial. Study of typical applications. Textbook: Scott MacKenzie, The 8051 Microcontroller, Mac Millan Publishing Company, 1992.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
Properties, limitations and characteristics of operational amplifiers. Linear and non-linear electronic circuits with operational amplifiers. Computerized simulation of the different devices. Basic logical sluices. Study of the operational systems of Flip-Flops, counters and registers, and parts of a microcontroller. Programming techniques based on microcontrollers. Application design based on microcontrollers. Textbook: Robert Boytlestand and Louis Nashelsky, Electronics: Theory of Circuits, Prentice Hall Hispanoamericana, 5th edition.
CAMPUS: CCM, CEM, MTY, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00862. TRANSMISSION MEDIA
Principles of electromagnetic wave transmission through different means such as air, metallic waves and transmission lines. Friis equation and decibels in telecommunications. Reflection and refraction of different interfaces. Coupling method using Smith map. Textbooks: Joel Ruiz de Aquino, Microondas: propagación y radiación, Impresos, ITESM, Campus Monterrey, segunda edición, 1995.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00863. INTEGRATED ANALOGICAL SYSTEMS
Analysis of commonly used types of conditioning signals. Operational amplifiers: functional blocks and other important applications. Instrumentation and isolation amplifiers. Operational principles of sinusoidal oscillators and relaxation oscillators. Study of A/D, D/A, V/F and F/V conversion techniques. Textbooks: Sedra and Smith, Microelectronic Circuits, Saunders College Publishing, 1991. Jacob, Industrial Control Electronics- Applications and Design, Prentice Hall, 1988.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00864. DIGITAL ELECTRICAL ENGINEERING
Solving linear equations through interactive methods in matrix algebra. Solutions of non-linear systems. Problems of boundary values for differential equations and electronic system design and simulation. Textbooks: Bruce Carnahan, Digital Computing and Numerical Methods, Wiley.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00871. ELECTRICAL ENGINEERING
Understanding electrical systems' principles of operation. Understanding and application of direct current electrical circuit principles (D.C.) and alternate currents (A.C.). Knowledge of the functions of instruments used for measuring electrical variables. Basic principles of operation of transformers and electronic devices. Familiarization with general characteristics of electrical installations for home, commercial or industrial purposes. Textbook: V. del Toro, Fundamentos de Ingeniería Eléctrica, Prentice Hall, segunda edición, 1988.
CAMPUS: CCM, CEM, MTY, QRO.
ACAD. PERIOD: FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00872. ELECTRICAL INSTALLATIONS
Definitions and requirements for electrical installations. Study of voltage systems, derived circuits and supplier circuits. Study of conductor capacity for general wiring. Overcharge protection of systems and equipment. Controllers, motor circuits, transformers and substations. Electrical installation, short circuit calculus and protection systems. Textbook: National Fire Protection Association, National Electrical Code (ANSI/NFPA 70), 1993 Edition, Editorial NFPA, 1993.
CAMPUS: CCM, CEM & MTY
ACAD. PERIOD: FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00873. COMMUNICATIONS SYSTEMS
Principles of probability and statistics for communications systems. Electrical noise in analog-communication systems. Basic PCM codification concepts and variables. Digital transmission graphics in base band and modulated forms. Scheme for optimal detection graphics and comparison of communication performance through graphics. Information theories and their application in scheme of source codification and of codification for detecting and correcting errors. Textbook: Jerry D. Gibson, Principles of Digital and Analog Communications, MacMillan, 2nd edition, 1993.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: FALL
LANGUAGE OF INSTRUCTION: SPANISH
. E00881. ENGINEERING PROJECTS I
Methodology for carrying out projects. Identifying problems and
areas of opportunity in electronic design. Proposing solutions
and analyzing their feasibility. Defining criteria for evaluating
the solution. Studying alternatives and choosing the optimal solution.
. E00882. ENGINEERING PROJECTS II
Implementing the solution to a problem in electronic design. Creating
technical documentation related to the project's development.
Analyzing the results and impact of the solution. Defending the
project.
. E00883. POWER SYSTEMS ANALYSIS
Components and types of analyses for power systems. Phase analysis
in single-phase and three-phase circuits in power systems. Symmetric
components in power circuits. Analysis of power circuits applying
equivalent transformer circuits. Application of the unit system.
Parameters for power lines. Models of power lines. Symmetric faults
in power systems. Textbook: J. Duncan Glover and Mulukutla Sarma,
Power System Analysis and Design, PWS Publishing Co., 2nd ed.,
1994.
. E00885. VIDEO SYSTEMS
Generation, transmission and reception of black-and-white and
color image signals. Aspects of synchronism of video and audio
signals; localization within the assigned television channels.
Superheterodyne system, opening-mask kinescope and main electronic
circuits, sweep and video signal processors. Digital TV, teletext,
videotext, and close-caption technologies. Textbook: Bernard Grob,
Basic Television and Video Systems, McGraw Hill, 1984.
E00935. LABORATORY: DIGITAL SYSTEMS
Study of different logical family sluice parameters. Arithmetic and combinational logical function installations as well as diverse oscillating circuit installations. Understanding circuits that use memory devices. Principles of operation and programmable logical circuit design. Design of logical circuits for different types of sequential control systems and development of simple control graphics. Study of the SM-51 card based on the 8051 model and principles of operation based on software and hardware. Development of simple programs that estimate the 8051 microcontroller's capacity. Application of the most important peripherals such as parallel ports, counters-temporizer and serial ports for simple problem solving. Different control applications. Textbook: Juan M. Hinojosa and Martha S. López, Manual del Laboratorio de Sistemas Digitales, ITESM, 1995.
CAMPUS: CCM, CEM, MTY, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00951. ENERGY CONVERSION LABORATORY
Study of equipment limitations and capacity. Use of tools and equipment such as transformers, direct current mechanisms, synchronic mechanisms, induction and monophase motors. Knowledge of size, capacity and precision of equipment and components. The student is expected to experiment and compare results to theoretical concepts as well as develop communications skills for expressing these. Group work is expected to research bibliographical material that relates to the course. Textbook: Javier Rdz., Bailey, Homero Núñez, Salvador Acevedo and Carlos Luna, Laboratorio de Conversión de Energía Electromagnética, ITESM, 1993.
CAMPUS: CCM, CEM & MTY
ACAD. PERIOD: FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00952. ELECTRICAL MEASUREMENT SYSTEMS LABORATORY
This course introduces the student to the proper usage of equipment for measurement in the electrical laboratory. Knowledge and usage of methods and procedures for measurement of units such as voltage, current, resistance, capacitance and inductance. Observation of RL, RC and RLC circuits in a transitory and sinusoidal steady state. Introduction to the PSpice simulator for analyzing circuits. Textbook: Stanley Wolf and Richard Smith, Guía para Mediciones Electrónicas y Prácticas de Laboratorio, Prentice Hall Hispanoamericana, 1992.
CAMPUS: CCM & CEM
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00953. CIRCUITS AND MEASUREMENT SYSTEMS LABORATORY
This course introduces the student to the proper usage of equipment for measurement in the electrical laboratory. Usage of general instruments such as multimeter, function generators, oscilloscope, impedance bridges, etc. Knowledge of security norms and analysis of errors in measurement. Proving basic principles and laws of electrical systems such as the following: Kirchhoff Laws, theorems by Thévenin and Norton, principles of linearity, superposition and duality. Introduction to the PSpice simulator for the analysis of electrical circuits. Textbook: Stanley Wolf and Richard Smith, Guía para Mediciones Electrónicas y Prácticas de Laboratorio, Prentice Hall Hispanoamericana, 1992.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: SPRING & FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00954. LABORATORY: ELECTRONICS
Understanding data sheet of semiconductor devices. Improvement of computer electronic circuit simulators. Designing power sources. Implementing signal conditioning circuits through operational amplifiers. Usage of sensors and transducer design. Designing power interfaces and impressed circuits. Textbook: Bolylestad and Nashelsky, Electronic Devices and Circuit Theory, Prentice Hall, 1992. Jacob, Industrial Control Electronics, Applications and Design, Prentice Hall, 1988.
CAMPUS: CCM, CEM & MTY
ACAD. PERIOD: FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00971. ELECTRONIC DESIGN LABORATORY
Interpretation of data sheets of semiconductor devices. Special analysis of analog simulators as an element for electronic designs. Design of power sources and audio amplifiers. Implementation of signal conditioning circuits and oscillators with operational amplifiers. Usage of sensors and transductor design. Designing systems for data acquisition. Usage of optoelectronic devices. Design of power interfaces and impressed circuits. Application of concurrent engineering systems to original electronic equipment models. Textbooks: Sedra and Smith, Microelectronic Circuits, Saunders Collage Publishing, 1991. Boylestad and Nashelsky, Electronic Devices and Circuit Theory, Prentice Hall, 1992. Jacob, Industrial Control Electronics-applications and Design, Prentice Hall, 1988.
CAMPUS: CCM, CEM, MTY, CVC, QRO.
ACAD. PERIOD: FALL
LANGUAGE OF INSTRUCTION: SPANISH
E00973. COMMUNICATIONS SYSTEMS LABORATORY
Spectrum analysis and its application to signal and pass-band
filter analysis. AM and FM system generation. Opto-electronic
coupling. Signal sampling and time-division multichanneling (TDM),
synchronization, pulse codification modulation (PCM), delta modulation.
Microwaves: generation, detection, basic measurements, impedance
measurement and coupling. Television: radio-frequency voltage
measurements, TV set adjustment and video signal analysis. Amplitude
shift keying (ASK) with and without white noise; frequency shift
keying (FSK) with and without white noise; phase shift keying
(PSK) with and without white noise. Textbook: Ricardo Guzmán
Díaz, Jaime O. Estevané V. and Joel Ruiz de Aquino,
Laboratorio de sistemas de comunicaciones eléctricas, Impresos
ITESM, 3rd ed., 1995.
E00899. FIELD PROJECTS IN INDUSTRY AND BUSINESS
Develop as a team (with other students and/or company personnel) the systems
or subsystems related to Electronic and
Communications Engineering,such as the design of electronic instrumentation
of varied application, development of software,
integration of computing systems and networks,integration of communications
systems, process instrumentation, technical-practical investigations related
to one’s major field of study. As well as the carrying out of corrective
maintenance, technical support, and training courses with specific and measurable
objectives.
LANGUAGE OF INSTRUCTION: SPANISH