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Signal Theory

Lecture

Lecturer:
dr inż. Tomasz Grajek (Ph.D. Eng.)

Initial requirements

Knowledge of trigonometry and analytic geometry, particularly operations on vectors.
Knowledge of the principles of differential and integral calculus. Proficiency in calculating definite integrals of trigonometric, exponential and power functions and polynomials. Proficiency in calculating the integrals of combined functions.
Good knowledge of complex numbers (Cartesian and polar form).
Function analysis. Efficient function plotting.
Knowledge of issues related to the sequences and series of numbers. The ability to determine the convergence of the series by various criteria. Ability to calculate the limits.
Knowledge of the basic laws of physics, especially related to the flow of electric current.

Signal Theory - course overview

Fundamental concepts and measures

Signals and their models
Signal classes and examples

Continuous, discrete, analogue, quantized and digital signals
Periodic signals
Sinusoidal signals: real and complex
Non-periodic signals

Basic signal metrics

Amplitude
Mean value
Energy of a signal
Power of s signal
Effective value of a signal (RMS)

Energy signals vs power signals
Orthogonality. Orthogonal signals and vectors
Signal components

DC and AC signal components
Odd and even signal components

Analysis of periodic signals using orthogonal series

Hilbert space
Orthogonal bases
Orthogonal series of functions
Trigonometric Fourier series
The influence of signal symmetries on the coefficients of the trigonometric Fourier series
Complex exponential Fourier series
The harmonic spectrum of a real signal
The relationship of the complex exponential and the trigonometric Fourier series
Linearity of Fourier series
The influence of signal symmetries on the coefficients of complex exponential Fourier series
The effect of signal shift in time on the complex exponential Fourier series
Spectrum of a product of two signals
Computing the power of a signal – the Parseval theorem

Analysis of non-periodic signals. Fourier Transformation and Transform

An intuitive introduction
Definition
Fourier Transform vs Laplace Transform
The Magnitude Spectrum and Phase Spectrum
Symmetries of the Fourier Transform for real-valued signals
Special case of Fourier Transform for symmetrical signals
Theorems describing the properties of Fourier Transformation

Linearity
Shift theorem – shifting in time domain
Shifting in frequency domain (also known as modulation theorem)
Scaling theorem (also called the similarity theorem)
Time-frequency duality (also known as the symmetry theorem)
Derivative theorem (differentiation in time domain)
Integration theorem

Calculating energy of the signal from its Fourier transform. The Parseval's theorem
Generalization of the Fourier transformation for infinite energy signals
Fourier transform of a periodic signal
Calculating the power of a signal from its Fourier transform. The Parseval's theorem for power signals

Processing of signals by linear and time invariant (LTI) systems

Introduction to LTI systems. Fundamental properties
Impulse response of an LTI system
Impulse response of a causal system
The response of an LTI system to arbitrary input
Properties of linear convolution
Frequency response
Determining the frequency response of an electronic circuit
Filters

Sampling. Discrete-time signals

Introduction to discrete signals
Spectrum of a sampled signal
Spectral efect of sampling a continuous signal
Reconstruction of the continuous signal from its samples
Non-periodic and periodic discrete-time signals
Fourier transforms of discrete-time signals
Processing of discrete-time signals
Frequency response of discrete-time LTI systems

Basic bibliography

A. Oppenheim, A. Wilsky, I. Young, Signals and Systems, Prentice Hall, 1996
R.A. Gabel, R.A. Roberts, Signals and Linear Systems, Wiley, 1986
B.P. Lathi, Linear Systems and Signals, Oxford University Press, 2004
E. Kamen, Introduction to Signals and Systems, MacMillan, 1987