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In the na m e of Allah

In the na m e of Allah. the compassionate, the merciful. Signals & Systems. S. Kasaei Sharif University of Technology E-Mail: skasaei@sharif.edu Home Page: http://sharif.edu/~ceinfo http://mehr.sharif.edu/~ipl http:// sharif.edu /~skasaei.

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In the na m e of Allah

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  1. In the name of Allah the compassionate, the merciful

  2. Signals & Systems S. Kasaei Sharif University of Technology E-Mail: skasaei@sharif.edu Home Page: http://sharif.edu/~ceinfohttp://mehr.sharif.edu/~ipl http://sharif.edu/~skasaei

  3. Course Syllabus

  4. Course Syllabus • Lecture: Sundays, 16:30-18:00, & Tuesdays, 16:30-18:00, room 205. • Website: http://ce.sharif.edu/~ce242/ http://mehr.sharif.edu/~ipl/courses/ce40242/index.html Check this site often for important announcements, files needed for computer exercises, and the PDF versions of handouts & homework. • Course Description: 40-242 provides an introduction to signals & systems fundamental principles & techniques.

  5. Course Syllabus • Topics include: Linear time-invariant systems, Fourier series representation of periodic signals, continuous-time Fourier transform, discrete-time Fourier transform, time & frequency characterization of signals & systems, sampling, Laplace transform, and Z transform. • Prerequisites: Electrical Circuits (40-121), Engineering Mathematics (22-041).

  6. Course Syllabus • Text Book: • Signals & Systems, by Alan V. Oppenheim & Alan S. Willsky, with H. Nawab, Prentice-Hall, 2nd Edition, 1997 (translated by Mr. Dayyani). [Additional topics might be included.] • Digital Signal Processing, by John G. Proakis & Dimitris G. Manolakis, Prentice-Hall, 3rd Edition, 1996. • Written & Computer Exercises: Written homework problems and computer exercises will be assigned over the course.

  7. Course Syllabus • Exams: There will be two midtermsand one final term exam.  • Grading Policy: Written & computer exercises: 3+2=5 Points Midterm exams: 3 Points each (hold at: 17.8.1382 & 29.9.1382) Final exam: 9 Points (hold at: 27.10.1382, 14 PM) Class activities:2 Points

  8. Course Syllabus • Instructor Office Hour: Tuesdays, 10:00-12:00, room CE 303. • Teaching Assistants: Mr. Abbas Javadtalab, & Mr.Hamzeh Ahangari. Sundays, 11:30-12:30, Khodro Bld., room 203. Course E-Mail: sut_ipl@yahoo.com

  9. Introduction to Signal & Systems

  10. Introduction • Concept of signals & systems arise in a wide variety of fields including: communications, circuit design, acoustic, biomedical engineering, speech processing, image processing, and the forth. • A signal represents the changes of a physical phenomenon (quantity)as a function of independent variables (usually time). • In other words, signals are functions of one or more independent variables that contain information about behavior or nature of some phenomenon.

  11. Introduction • A system is defined as a physical devise that performs an operation on a signal. • A physical systems in the broadest sense is an interconnection of, components, devices, or subsystems (automobile, human body). • A system not only includes physical devices, but also software realizations of operations on a signal.

  12. Introduction • Systems respond to particular signals by producing other signals or some desired behavior. • When we pass a signal through a system, we say that we have processed the signal. • A system can be viewed as a process in which input signals are transformed by the system or cause the system to respond in some way, resulting in other signal as outputs.

  13. Introduction • Voltages & currents as a function of time in an electrical circuits are examples of signals. • A Circuit is an example of a system; which responds to applied voltages and currents. • When an automobile driver depresses the accelerator pedal, the automobile responds by increasing the speed [system: automobile, input: pressure on the accelerator pedal, response: automobile speed].

  14. Introduction • System:computer program,input:digitized signal,respond:output signal/description. • System:camera,input:light from different sources & reflected from objects,respond:photograph. • System:robot arm, input: control inputs,respond:arm’s movement. • The method or set of rules for implementing the system by a program, is called an algorithm.

  15. Introduction • We might be interested in: • Characterizing presented systems to understand how it will respond to various inputs [circuit analysis]. • Designing systems to process signals in particular way [image restoration & compression]. • Extract specific pieces of information from signals [future behavior prediction]. • Control the characteristics of a given system [control systemdesign].

  16. Introduction • Information in a signal is contained in a pattern of variations in some form. • Signals can be classified into 4 different categories depending on the characteristics of independent variables (time) & values they take, as: • Continuous-time [e.g. speech] (analog signal), • Discrete-time [e.g. daily average temperature], • Continuous-valued, & • Discrete-valued (& discrete-time  digital signal).

  17. Introduction • Mathematical analysis & processing of signals requires the availability of a mathematical description for the signal, called signal model. • Continuous and discrete signals can be of random or deterministic type. • Any signal that can be uniquely described by an explicit mathematical expression, a table of data, or a well-defined rule is called deterministic.

  18. Introduction • Deterministic term is used to emphasize that all past, present, and future values of the signal are known precisely, without any uncertainty. • In practice, there are signals that either cannot be described to any reasonable degree of accuracy by explicit mathematical formulas, or such a description is too complicated to be of any practical use. • Such signals evolve in time in an unpredictable manner & are referred to as random signals.

  19. Introduction • This provides motivation for the analysis & description of random signals using statistical techniques instead of explicit formulas. • The mathematical framework for the theoretical analysis of random signals is provided by the theory of probability & stochastic processes. • In general, signal & system analysis is constantly evolving & developing in response to new problems, techniques, & opportunities.

  20. The End

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