E95005. Electronic System Design Based on PIC Microcontrollers
Academic department: Electronic
& Electrical Engineering
Units: 3-0-8
Requirement: E 00856 , CS00002
Equivalence: ninguna
Semester and career: 8°semestre de IEC e ISE
General aim of the course:
Este curso está dirigido a los alumnos interesados en el diseño
de sistemas electrónicos gobernados por microcontroladores. El curso
está orientado al manejo de dispositivos que se emplean generalmente
en la instrumentación, en el control y en el diseño de interfaces
entre dispositivos analógicos y digitales. Durante el curso se aplicarán
técnicas de acondicionamiento de señales y manejo de actuadores.
El alumno explotará las ventajas que ofrece el uso de un compilador de
C, como herramienta de programación, sin perder de vista las bases de
la programación en ensamblador y el conocimiento de la arquitectura interna
del microcontrolador. Aprenderá el manejo de los recursos especiales
del microcontrolador
Si bien, el curso está orientado al manejo de PIC16F877, los conocimientos
adquiridos se podrán extrapolar a otros microcontroladores. Por otro
lado, con el fin de ofrecer otras alternativas, durante el curso se revisarán
otros microcontroladores de la misma familia.
Bibliography: Texto:
1. Microcontroladores PIC : Diseño Práctico De Aplicaciones, Segunda
parte PIC 16F87X
By: José Ma. Angulo Usategui, Susana Romero Yesa E Ignacio Angulo Martínez
McGraw-Hill,c2000
2. PIC16F87X Data sheet
By: Microchip. www.microchip.com
Consulta:
3. C Compiler Reference Manual
By: Custom Computer Services Inc.
August 2002
4. PICmicro MCUC. An introduction
to programming the Microchip PIC in CCS C
By Nigel Gardner
5. PIC : Your Personal Introductory
Course
By: John Morton
Newnes, 2001
6. An Introduction To The
Design Of Small-Scale Embedded Systems
By: Tim Wilmshurst
Palgrave, 2001.
7. Design With Operational
Amplifiers And Analog Integrated Circuits
By: Sergio Franco.
McGraw-Hill, 2002.
8. Electronic Circuit Analysis
And Design
By: Donald A. Neamen
Irwin, 1996
9. MPLAB IDE versión
6.40
PICSTART PLUS System
Instructor's profile: Profesor
con Doctorado o Maestría en ingeniería eléctrica o ingeniería
electrónica. Con experiencia en el diseño de sistemas analógicos
y sistemas basados en microcontroladores.
Language of Instruction: Spanish
E95007. Advanced mobile telephony
Academic department: Electric
Engineering
Units: 3-0-8
Requirement: E 95 006
Equivalence: None
Semester and career: 8°, 9° IEC
General aim of the course: This topic is focus on apply the fundamentals of digital and mobile telephony. Mainly, the course continue the theory of the telephony, beginning from the "Telefonica Digital y Celular" (E 95 006 ) topic. The course emphasizes the design aspect and of course, the optimization issues on this design.
Bibliography: Map info Professional
User's guide
Ver. 6.5
May 2001.
Troy, New York, USA
Digital telephony and network integration. Bernhard E. Keiser and Eugene Strange. New York : Van Nostrand Reinhold, c1995, 2nd ed
Telecommunications Primer
E. Bryan Carne Second Prentice Hall 1999 0-13-022155-4
The Telecommunications Handbook Terplan/Morreale
CRC Press 2000 0-8493-3137-4
The Fundamentals of Wireless
Communications Course
The Fundamentals of Cellular Communications Technologies
The Personal Communications Services
Copyright(c) 1998 Bellcore.
CDMA RF System Engeenering
1998 Artech house Inc.
685 Canton Street
Norwood MA, USA
Instructor's profile: Master
on Science or Engineering or PHD on Electrical Engineering, electronics or Telecommunications,
specialized on digital telecommunications.
Language of Instruction: Spanish
Equivalence: None
General aim of the course: Audio is a powerful communication
tool and an important part of our daily life. The audio industry is growing
rapidly as communication and entertainment markets develops, demanding engineers
capable of designing audio systems to fulfill the new challenges.
This course is intended to be an introductory one to Audio Engineering.
Basic topics such as psychoacoustics, loudspeakers and enclosures, microphones,
digital signal processing of audio, and power audio amplifiers are covered.
Special emphasis to practical and laboratory work is given through the construction
of several audio projects.
Campus:Querétaro
Bibliography:
Dickason, Vance, "The Loudspeaker Design Cookbook", Peterborough,
N.H., Audio Amateur, 2000. 6th Ed., ISBN 1882580338.
Watkinson, John, "Audio Digital", International Thomson ; Paraninfo,
1996. ISBN 8428323194.
Loud Speaker and Headphone Handbook", Edited by John Borwick, with specialist
contributors, Boston, MA : Focal Press, 2001, 3er Ed., ISBN 0240515781.
Instructor's profile: Master in Science in Electrical Engineer
(electronics) or in other related field.
Language of Instruction:Spanish
E95039. Teleengineering Laboratory
Academic department:Electrical
Engineering
Units:2-2-8
Requirement:E00832 Electric Circuits II and E00836 Digital Systems II
Semester and career:5th IEC
Equivalence:Without
General aim of the course:The
course integrates the electronic, telecommunication and computing technologies
through the development of systems for:
Acquisition, analysis and presentation of remote data, Processes automation
from a distance, Man-Machine interfaces and, Computer aided remote monitoring
and controlling processes.
Campus:Monterrey
Bibliography:Hans Berger, Automating
with STEP 7 in LAD and FBD,Publicis MCD Verlag, Germany, 2000
Manuel E. Macías, Programación Gráfica para Instrumentación
y Control, ITESM, Campus Monterrey, Depto. de Ingeniería Eléctrica,
2001Robert H. Bishop, LabVIEW Student Edition 6i, Prentice Hall, 2001
Instructor's profile:Professor with M.S. or Ph.D. in Electric Engineering or
Electronic Engineering and, professional experience in industry or experience
in development or research projects in the area of instrumentation, automation
or control.
Language of Instruction:Spanish
E95040. Applications with microcontrollers and PDAs
Academic department:Electrical
Engineering
Units:3 0 8
Requirement:None
Semester and career:6
Equivalence:None
General aim of the course:To
continue the education in digital systems design by introducing the student
to the building of practical applications using microcontrollers and personal
digital assistant (PDAs).
Campus:Monterrey
Bibliography:Dhananjay V. Gadre, "Programming and customizing the AVR microcontroller",
McGraw-Hill 2001
Klaus Kühnel, "AVR RISC Microcontroller Handbook",
Newnes 1998
Ted Van Sickle, "Programming microcontrollers in C", Motorola Series
in
Solid-State Electronics
Instructor's profile:Professor with a specific background in the construction
of practical systems with microcontrollers and/or personal digital assistants,
preferably with a Ph.D. in digital systems.
Language of Instruction:Spanish
E95041. Heterogeneous System Design
Academic department: Electrical
Engineering
CLU: 3/0/8
Prerequisite: E00-857
Equivalence: None
The objective of this course is to design, model and co-simulate heterogeneous systems initially with hardware and software components. Also, the modeling of the system gradually incorporates components such as analog components and other non-electronic components. The design specification and co-simulation of the systems is going to require the use of technological aids such as hardware description languages, SystemC, and other industry standard development tools.
Bibliography
Textbook:
• J. Bhasker, “A SystemC primer”, Star Galaxy Publishing,
2002| ISBN 0-9650391-8-8
Reference:
• Grötker, Liao, Martin, Swan, “System Design with SystemC”,
Kluwer, Academia Publishers, 2002 | ISBN 0-306-47652-5
• Felice Balarin et al.”Hardware-Software Co-Design of Embedded
Systems: The POLIS approach”, Kluwer Academic Publishers, 1997 | ISBN
0-7923-9936-6.
• J. Bhansker, “A VHDL primer”, Prentice Hall, Third Edition,
1999| ISBN 0-13-096575-8.
Professor background
Instructor must hold a Ph.D. in Electrical Engineering, Computer Engineering
and related areas. The instructor must have research or industry experience
related to embedded system design and application specific integrated circuit
design.
E95042. Biomedical Instrumentation
Academic department:E
Units:2-1-8
Requirement:E00863 or E00861
Semester and career:8º IEC, 7º IMT
Equivalence:NT
General aim of the course:To introduce the students to the principles, applications
and design of medical instrumentation applied to the measurement of the most
important biosignals.
Campus:Edo. México
Bibliography:Joseph J. Carr & John M. Brown, Introduction to Biomedical
Equipment Technology, Prentice Hall, ISBN: 0-13-010492-2, 4a. edición,
2001.
John G. Webster (Editor), Bioinstrumentation, John Wiley & Sons, ISBN: 0-471-26327-3, 1a edición, 2004.
John G. Webster (Editor), Medical Instrumentation: Applications and Design, John Wiley & Sons, ISBN: 0-471-15368-0, 3a. edición, New York, 1998.
Instructor's profile:Master of Science in Biomedical Engineering, Bioelectronics, Electrical, Engineering, Electronics Engineering or similar. Preferably with experience in projects related to applied research and development of medical instrumentation.
Language of Instruction:Spanish
Academic department:Electrical
and Electronics Engineering
Units:3-0-8
Requirement:F-00-001 and Ma-00-841
Semester and career:4 IEC, 5 IFI, 5 ISE
Equivalence:none
General aim of the course:To use the statistical-mechanical and quantum-mechanical
frameworks in the analysis of solid-state device properties and to provide the
physical rudiments necessary in the characterization of semiconductor-based
devices such as transistors, diodes, optoelectronic components and microelectromechanic
systems. The student is expected to apply mathematical models (Bloch, Kronig-Penney)
to understand the behavior of intrinsic and extrinsic semiconductors under equilibrium
conditions.
Campus:Cd. México
Bibliography: • Ferry, David K. and Jonathan Bird. Electronic Materials
and Devices. Academic Press, 2001. ISBN 01-2254-161-8.
• Grahn, Holger T.
Introduction to Semiconductor Physics. World Scientific, 1999. ISBN 98-1023-302-7.
• Hamaguchi, Chihiro. Basic Semiconductor Physics. Springer-Verlag, 2001.
ISBN 35-4041-639-0.
• Kittel, Charles. Introduction to Solid State Physics. Wiley, 1998. ISBN
04-7111-181-3.
• McKelvey, John P. Solid State and Semiconductor Physics. Krieger Publishing
Company, 1982. ISBN 08-9874-396-6.
• McKelvey, John P. Solid State Physics for Engineering and Materials Science. Krieger Publishing Company, 1993. ISBN 08-9464-436-X.
• Navon, Charles. Electronic Materials and Devices. Houghton-Mifflin, 1976. ISBN 03-9518-917-9.
Instructor's profile: Specialist
in solid-state physics or solid-state electronics with an M. Sc. or Ph. D. degree
Language of Instruction:spanish
E95049.Microdevice fabrication
Academic department:Electrical
and Electronics Engineering
Units:3-0-8
Requirement:Semiconductors
Semester and career:5 IEC, 6 IFI, 6 ISE
Equivalence:E-85-046
General aim of the course:To understand and analyze the main technologies available
for the fabrication of integrated circuits and microelectromechanical systems,
emphasizing the scientific underpinnings, the available tools and the economic
and environmental factors. To describe the operation of microsystems. To explain
the fundamental laws governing the behavior of devices at micrometric and nanometric
scales. To evaluate the possible future trends in nanotechnology.
Campus:Cd. México
Bibliography:• Plummer, J.D.; M.D. Deal and P.B. Griffin. Silicon VLSI
Technology. Prentice-Hall, 2003. ISBN 0-13-085037-3.
• Gad-El-Hak, M. The
MEMS Handbook. CRC Press, 2001. ISBN 084-930-077-0.
• Madou, Marc J. Fundamentals of Microfabrication: The Science of Miniaturization,
2nd ed. CRC Press, 2002. ISBN 084-930-826-7.
• Navon, Charles.
Electronic Materials and Devices. Houghton-Mifflin, 1976. ISBN 03-9518-917-9.
• Pelesko, John A. and David H. Bernstein. Modeling MEMS and NEMS. CRC
Press, 2002. ISBN 158-488-306-5.
• Razavi, Behzad. Design of Analog CMOS ICs. McGraw-Hill, 2000. ISBN 007-238-032-2.
• Van Zant, Peter. Microchip Fabrication. McGraw-Hill, 2000. ISBN 007-135-636-3.
Instructor's profile: Specialist
in solid-state physics or solid-state electronics with an M. Sc. or Ph. D. degree
Language of Instruction:spanish
Academic department: Electronic
& Electrical Engineering
Units:3-0-8
Requirement:Control I & Control II
Semester and career:9th Electronics & Communications Engineering , 9th Electronic
Systems Engineering
Equivalence:none
General aim of the course:The ever increasing technological demands of today
call for very complex systems, which in turn require
highly sophisticated controllers to ensure that high performance can be achieved
and maintained under
adverse conditions. There are needs in the control of these complex systems
which cannot be met by
conventional approaches to control. For instance, there is a significant interest
in enhancing current
avionic systems so that they can reconfigure the aircraft controls to maintain
adequate levels of
performance even if there are complete failures in one or more of the actuators
or sensors. In a similar
manner, there is a significant need to achieve higher degrees of autonomous
operation for robotic
systems, spacecraft, manufacturing systems, automotive systems, underwater and
land vehicles, and
others. To achieve such highly autonomous behavior for complex systems one can
enhance today's
control methods using intelligent control systems and techniques. [IEEE]
Campus:Cd. México
Bibliography:1. www.mathworks.com
2. www. neurolab.com
3. Intelligent Control Systems Using Soft Computing Methodologies
by Ali Zilouchian , Mohammad Jamshidi
4. Fuzzy Logic and Control: Software and Hardware Applications, Vol.2
by Mohammad Jamshidi,
5. Robust Control Systems with Genetic Algorithms
by Mohammad Jamshidi
6. oft Computing: Fuzzy Logic, Neural Networks, and Distributed Artificial Intelligence
(Prentice Hall Series on Environmental and Intelligent Manufac)
by Fred Aminzadeh , Mohammad Jamshidi
7. A First Course in Fuzzy Logic, Second Edition
by Hung T. Nguyen, Elbert A. Walker
8. Fuzzy Thinking: The New Science of Fuzzy Logic
by Bart Kosko
9. Introduction to Fuzzy Sets, Fuzzy Logic, and Fuzzy Control Systems
by Trung Tat Pham, Guanrong Chen
10. Fuzzy Automata and Languages: Theory and Application
by Davender S. Malik, John N. Mordeson
11. Understanding 99% of Artificial Neural Networks : Introduction & Tricks
by Marcelo Bosque
12. Fundamentals of Neural Networks
by Laurene V. Fausett
13. Learning Bayesian Networks
by Richard E. Neapolitan
14. A First Course in Fuzzy and Neural Control
by Hung T. Nguyen, Nadipuram R. Prasad, Carol L. Walker, Ebert A. Walker
15. Neural Networks for Modelling and Control of Dynamic Systems: A Practitioner's
Handbook
by Magnus Nrgaard, O. Ravn, N. K. Poulsen, Peter M. Norgaard, Lars K. Hansen
Instructor's profile: Professor with PhD in Control, mechanical, electrical
or electronic engineering, with experience in the development of artificial
intelligent systems.
Language of Instruction: spanish
E95070.
Wireless communications systems I
Academic department: Electrics
and Electronics Engineering
Units:3-0-8
Requirement:E 00018 Digital Telephony or equivalent
Semester and career:7-8-9 IEC
Equivalence:None
General aim of the course:Identify, describe and deferenciate the elements of
an radiolink and satellital system, for industry purpouses. To analyse and select
the instruments for a specific application, using techniques from MMDS and LMDS
technologies, satellital equipments and acess techniques. To know and differentiate
the radio and satellital systems.
Campus:Seleccionar Campus
Bibliography:Winch Robert G. Telecommunications transmissión system.
Mc Graw Hill, 1a ed. ISBN: 0-07-113768-8
Instructor's profile:Ph D or Master in Telecommunications Engineering, with
a practical experience in wireless networking applications.
Language of Instruction:Spanish
E95086. CMOS analog microelectronics
Academic
department:IE
Units:3-0-8
Requirement:E00863-Analog Integrated Circuits
Semester and career:Elective course in the following career programs: IEC,
IMT, IFI, ISE
Equivalence:None
General aim of the course:The purpose of this course is to enable the student
to model, analyze and design analog integrated circuits using CMOS technologies.
At the conclusion of the course, the student should be able to successfully
perform the electrical and physical design of operational amplifiers and other
important analog building blocks.
Campus:Monterrey
Bibliography:P. E. Allen, D. R. Holberg, CMOS Analog Circuit Design, Oxford
University Press, Second Edition, 2002. (textbook)
B. Razavi, Design of Analog CMOS Integrated Circuits, McGraw Hill, 2001.
D. A. Johns, K. Martin, Analog Integrated Circuit Design, John Wiley & Sons,
1997.
T. H. Lee, The Design of CMOS Radio-Frequency Integrated Circuits, Cambridge
University Press, 1998.
P. R. Gray, R. G. Meyer, P. J. Hurst, S. H. Lewis, Analysis and Design of Analog
Integrated Circuits, John Wiley & Sons, 4th Edition, 2001.
Instructor's profile:Professor with Ph.D. in Electronics
Language of Instruction:Spanish
E95091. Wireless communications systems II
Academic
department:Electrics and Electronics Engineering
Units:3-0-8
Requirement:E 00018 Digital Telephony or equivalent
Semester and career: 7-8-9 IEC
Equivalence:None
General aim of the course:Identify, describe and deferenciate the elements of
an cellular system, for industry purpouses. To analyse and select the instruments
for a specific application, using techniques from digital modulations, wireless
equipments and acess techniques. To know and differentiate the radiocommunication
systems and the localization systems.
Campus:Seleccionar Campus
Bibliography:Lee, William C.Y. Mobile Cellular Telecommunications
Mc Graw Hill, 2a ed. ISBN: 0-07-038089-9
Instructor's profile:Ph D or Master in Telecommunications Engineering, with
a practical experience in cellular networking applications.
Language of Instruction:Spanish
E95092. New generations in optical networks
Academic
department: Electrics and Electronics Engineering
Units:3-0-8
Requirement:E 00018 Digital Telephony
Semester and career:7-8-9 IEC, ISE
Equivalence:None
General aim of the course:Identify, describe and deferenciate the characteristics
of optical networks to analyse and select the elements for a specific application
or envolvement. To know and differentiate some classes of fiber optics and detect
problems in this kind of networking. Know PDH and SHD systems. Know the new
advances in optical communications systems.
Campus:Cd. México
Bibliography:Winch Robert G. Telecommunications transmissión system.
Mc Graw Hill, 1a ed. ISBN: 0-07-113768-8
Instructor's profile:Ph D or Master in Telecommunications Engineering, with
a practical experience in networking application.
Language of Instruction:spanish
E95098. Industrial Instrumentation
Academic
department:Electrics and Electronics Engineering
Units:3-0-8
Requirement:Mr00021 o E00863 Previous knowledge on linear systems
Semester and career:6-7 IEC, ISE & IMT
Equivalence:None
General
aim of the course:Identify, describe and deferenciate the elements of an instrumentation
loop, for industry purpouses, applying the measurements basic units and international
norms for industrial instrumentation. To analyse and select the instruments
for a specific application, using fundamental measurements elements: pressure,
level, temperture and flow; for the transmition processes and convertion and
for valves and linear actuators for industrial instrumentation loops. To know
and differentiate some classes of instrumental amplifiers, filtereing and different
structures of industrial controllers. Analyse and detect problems in the instrrumentation
loop. To know and differentiate the analitical instrumentation and basics of
virtual intrumentation.
Campus:Seleccionar Campus
Bibliography:Creus Antonio. Instrumentacion Industrial.
Alfaomega-Marcombo, 6a ed. ISBN: 970-15-0246-9
Instructor's profile:Ph D or Master in Control Engineering, Signal processing
or Instrumentation with a practical experience in Industrial Instrumentation.
Language of Instruction:Spanish
Fecha de última actualización: 13 de diciembre de 2004.(M)