Presentation is loading. Please wait.

Presentation is loading. Please wait.

ECE 802-603 Spring 2010 Introduction to ECE 802 Selin Aviyente Associate Professor.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "ECE 802-603 Spring 2010 Introduction to ECE 802 Selin Aviyente Associate Professor."— Presentation transcript:

1 ECE 802-603 Spring 2010 Introduction to ECE 802 Selin Aviyente Associate Professor

2 ECE 802-603 Spring 2010 Introduction Classical signal analysis focuses on two domains Time Domain: Amplitude, Energy, Correlation Frequency Domain: Power, Spectrum, Bandwidth Frequency domain analysis is done through FOURIER TRANSFORM

3 ECE 802-603 Spring 2010 Time Domain Analysis In the time domain, any signal can be expressed as: Expanded in terms of an infinite number of delta functions over the real axis with expansion coefficients equal to the amplitude.

4 ECE 802-603 Spring 2010 Spectrum Analysis Fourier transform is defined to be: Decompose a given time signal in terms of eternal sinusoids (complex exponentials) Expansion Coefficients=Spectral Power What is wrong with this??

5 ECE 802-603 Spring 2010 Disadvantages Not all signals are eternal  Most signals are time-limited. Gives us the global picture, no local information Most real life signals are not combinations of sinusoids. Fourier transform is sufficient for stationary signal analysis and LTI systems. How does the frequency change with time?

6 ECE 802-603 Spring 2010 Concept of Transients Transient: Any phenomena that is not stationary, has finite duration The human sensory system concentrates on the transients rather than the stationary for selecting important information. Examples: –A word pronounced at a particular time –Epilepsy pattern in brain waves –An object located in the corner of an image Most of signal processing is devoted to analyzing stationary signals and LTI systems.

7 ECE 802-603 Spring 2010 Example No temporal localization

8 ECE 802-603 Spring 2010 Example

9 ECE 802-603 Spring 2010 Time-Frequency and Wavelet Analysis Wavelets Expand signals in terms of localized functions (wavelets)  expansion coefficients  set of decomposing functions Linear Compare this to Fourier series Time-Frequency Distributions Expand the signal’s time- varying auto-correlation function in terms of sinusoids Fits sinusoids locally instead of globally Nonlinear

10 ECE 802-603 Spring 2010 Properties We will study how to choose these functions –Are there some particular functions to choose? –Is it signal adaptive? –General properties –How to design wavelets?

11 ECE 802-603 Spring 2010 Tools In order to determine, the ‘best’ set of functions to expand our signals, we need to define a space for our signals  Vector space After the ‘signal space’ is defined, we need to define a measure for quantifying how good any approximation is  Inner product Different sets of expansion functions  Basis

12 ECE 802-603 Spring 2010 Applications Biomedical Signal Processing Speech Processing Radar Analysis, Target Detection Blind Source Separation Image Compression (JPEG2000) Object Recognition

Download ppt "ECE 802-603 Spring 2010 Introduction to ECE 802 Selin Aviyente Associate Professor."

Similar presentations

For more ppt’s, visit www.studentsaarthi.com Fourier Series For more ppt’s, visit www.studentsaarthi.com.

For more ppt’s, visit Fourier Series For more ppt’s, visit
DCSP-11 Jianfeng Feng

DCSP-11 Jianfeng Feng
Signals and Fourier Theory

Signals and Fourier Theory
Lecture 7: Basis Functions & Fourier Series

Lecture 7: Basis Functions & Fourier Series
Fourier Series 主講者:虞台文.

Fourier Series 主講者:虞台文.
Fourier Integrals For non-periodic applications (or a specialized Fourier series when the period of the function is infinite: L  ) L -L L  -L  - 

Fourier Integrals For non-periodic applications (or a specialized Fourier series when the period of the function is infinite: L  ) L -L L  -L  - 
Fourier Transform – Chapter 13. Image space Cameras (regardless of wave lengths) create images in the spatial domain Pixels represent features (intensity,

Fourier Transform – Chapter 13. Image space Cameras (regardless of wave lengths) create images in the spatial domain Pixels represent features (intensity,
Extensions of wavelets

Extensions of wavelets
Outline Transmitters (Chapters 3 and 4, Source Coding and Modulation) (week 1 and 2) Receivers (Chapter 5) (week 3 and 4) Received Signal Synchronization.

Outline Transmitters (Chapters 3 and 4, Source Coding and Modulation) (week 1 and 2) Receivers (Chapter 5) (week 3 and 4) Received Signal Synchronization.
Properties of continuous Fourier Transforms

Properties of continuous Fourier Transforms
Computer Graphics Recitation 6. 2 Motivation – Image compression What linear combination of 8x8 basis signals produces an 8x8 block in the image?

Computer Graphics Recitation 6. 2 Motivation – Image compression What linear combination of 8x8 basis signals produces an 8x8 block in the image?
Computer Graphics Recitation 7. 2 Motivation – Image compression What linear combination of 8x8 basis signals produces an 8x8 block in the image?

Computer Graphics Recitation 7. 2 Motivation – Image compression What linear combination of 8x8 basis signals produces an 8x8 block in the image?
EECS 20 Chapter 10 Part 11 Fourier Transform In the last several chapters we Viewed periodic functions in terms of frequency components (Fourier series)

EECS 20 Chapter 10 Part 11 Fourier Transform In the last several chapters we Viewed periodic functions in terms of frequency components (Fourier series)
Intro to Fourier Analysis Definition Analysis of periodic waves Analysis of aperiodic waves Digitization Time-frequency uncertainty.

Intro to Fourier Analysis Definition Analysis of periodic waves Analysis of aperiodic waves Digitization Time-frequency uncertainty.
Paul Heckbert Computer Science Department Carnegie Mellon University

Paul Heckbert Computer Science Department Carnegie Mellon University
Autumn Analog and Digital Communications Autumn

Autumn Analog and Digital Communications Autumn
Basic Concepts and Definitions Vector and Function Space. A finite or an infinite dimensional linear vector/function space described with set of non-unique.

Basic Concepts and Definitions Vector and Function Space. A finite or an infinite dimensional linear vector/function space described with set of non-unique.
Multi-Resolution Analysis (MRA)

Multi-Resolution Analysis (MRA)
Introduction to Wavelets

Introduction to Wavelets
Continuous-Time Fourier Methods

Continuous-Time Fourier Methods

Similar presentations

Ads by Google