Fourier theory We know a lot about waves at a single  : n( , v p ( , R(  absorption(  … Analyze arbitrary in terms of these, because Fourier.

Slides:

Advertisements

Similar presentations

DCSP-11 Jianfeng Feng

Advertisements

Signals and Fourier Theory

Engineering Mathematics Class #15 Fourier Series, Integrals, and Transforms (Part 3) Sheng-Fang Huang.

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. Fourier Transform – continuous function Apply the Fourier Series to complex- valued functions using Euler’s notation to.

Leo Lam © Signals and Systems EE235. Fourier Transform: Leo Lam © Fourier Formulas: Inverse Fourier Transform: Fourier Transform:

EE-2027 SaS 06-07, L11 1/12 Lecture 11: Fourier Transform Properties and Examples 3. Basis functions (3 lectures): Concept of basis function. Fourier series.

Reminder Fourier Basis: t  [0,1] nZnZ Fourier Series: Fourier Coefficient:

Propagation in the time domain PHASE MODULATION n(t) or k(t) E(t) =  (t) e i  t-kz  (t,0) e ik(t)d  (t,0)

Intro to Fourier Analysis Definition Analysis of periodic waves Analysis of aperiodic waves Digitization Time-frequency uncertainty.

CSCE 641 Computer Graphics: Image Sampling and Reconstruction Jinxiang Chai.

CSCE 641 Computer Graphics: Image Sampling and Reconstruction Jinxiang Chai.

Fourier Transforms on Simulated Pulsar Data Gamma-ray Large Area Space Telescope.

Fourier Transforms on Simulated Pulsar Data Gamma-ray Large Area Space Telescope.

Signals Processing Second Meeting. Fourier's theorem: Analysis Fourier analysis is the process of analyzing periodic non-sinusoidal waveforms in order.

PROPERTIES OF FOURIER REPRESENTATIONS

Fourier Transforms on Simulated Pulsar Data Gamma-ray Large Area Space Telescope.

WHY ???? Ultrashort laser pulses. (Very) High field physics Highest peak power, requires highest concentration of energy E L I Create … shorter pulses.

S. Mandayam/ ECOMMS/ECE Dept./Rowan University Electrical Communication Systems ECE Spring 2009 Shreekanth Mandayam ECE Department Rowan University.

Marcus Ziegler SCIPP/UCSCPulsar Meeting 1/17/ Fourier Transform with differences on Simulated and Real Pulsar Data Gamma-ray Large Area Space Telescope.

Transforms: Basis to Basis Normal Basis Hadamard Basis Basis functions Method to find coefficients (“Transform”) Inverse Transform.

Feb. 7, 2011 Plane EM Waves The Radiation Spectrum: Fourier Transforms.

The Fourier Transform The Dirac delta function Some FT examples exp(i  0 t) cos(  0 t) Some Fourier Transform theorems Complex conjugate: f*(t) Shift:

Digital Image Processing, 2nd ed. © 2002 R. C. Gonzalez & R. E. Woods Chapter 4 Image Enhancement in the Frequency Domain Chapter.

Systems: Definition Filter

Discrete-Time Fourier Series

Image Processing Fourier Transform 1D Efficient Data Representation Discrete Fourier Transform - 1D Continuous Fourier Transform - 1D Examples.

1 Let g(t) be periodic; period = T o. Fundamental frequency = f o = 1/ T o Hz or  o = 2  / T o rad/sec. Harmonics =n f o, n =2,3 4,... Trigonometric.

Complex representation of the electric field Pulse description --- a propagating pulse A Bandwidth limited pulseNo Fourier Transform involved Actually,

The Story of Wavelets.

Outline  Fourier transforms (FT)  Forward and inverse  Discrete (DFT)  Fourier series  Properties of FT:  Symmetry and reciprocity  Scaling in time.

Fourier Series & The Fourier Transform What is the Fourier Transform? Fourier Cosine Series for even functions and Sine Series for odd functions The continuous.

1 Waves 8 Lecture 8 Fourier Analysis. D Aims: ëFourier Theory: > Description of waveforms in terms of a superposition of harmonic waves. > Fourier series.

Image Processing © 2002 R. C. Gonzalez & R. E. Woods Lecture 4 Image Enhancement in the Frequency Domain Lecture 4 Image Enhancement.

12. FOURIER ANALYSIS CIRCUITS by Ulaby & Maharbiz All rights reserved. Do not copy or distribute. © 2013 National Technology and Science Press.

Lecture 9 Fourier Transforms Remember homework 1 for submission 31/10/08 Remember Phils Problems and your notes.

lecture 4, Convolution and Fourier Convolution Convolution Fourier Convolution Outline  Review linear imaging model  Instrument response function.

Fundamentals of Electric Circuits Chapter 18 Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

EE104: Lecture 5 Outline Review of Last Lecture Introduction to Fourier Transforms Fourier Transform from Fourier Series Fourier Transform Pair and Signal.

Chapter 4 Fourier transform Prepared by Dr. Taha MAhdy.

Digital Image Processing, 2nd ed. © 2002 R. C. Gonzalez & R. E. Woods Background Any function that periodically repeats itself.

Spatial Frequencies Spatial Frequencies. Why are Spatial Frequencies important? Efficient data representation Provides a means for modeling and removing.

11. FOURIER ANALYSIS CIRCUITS by Ulaby & Maharbiz.

Fourrier example.

Chapter 4. Fourier Transformation and data processing:

Leo Lam © Signals and Systems EE235 Leo Lam.

The Story of Wavelets Theory and Engineering Applications

1 “Figures and images used in these lecture notes by permission, copyright 1997 by Alan V. Oppenheim and Alan S. Willsky” Signals and Systems Spring 2003.

Importance of phase in f(  )…review 11 waves101 waves Linear phase dependence:  t  is the same. Pulse is shifted What phase function makes a shift?

Frequency domain analysis and Fourier Transform

How To Say What You Want Describing Signals What have we learned? Any traveling sinusoidal wave may be described by y = y m sin(kx   t +  )  is the.

Math for CS Fourier Transforms

EE104: Lecture 6 Outline Announcements: HW 1 due today, HW 2 posted Review of Last Lecture Additional comments on Fourier transforms Review of time window.

Complex Form of Fourier Series For a real periodic function f(t) with period T, fundamental frequency where is the “complex amplitude spectrum”.

Image Enhancement in the

You play a song on two speakers (not stereo)

2D Fourier transform is separable

Concept test 15.1 Suppose at time

Lecture 35 Wave spectrum Fourier series Fourier analysis

Waves The first term is the wave and the second term is the envelope.

Fourier transforms and

Announcements Please return slides.

1. FT of delta function, : Go backwards with inverse:

Fundamentals of Electric Circuits Chapter 18

The Fourier Transform Some Fourier Transform theorems Scale: f(at )

Signals and Systems EE235 Leo Lam ©

More than meets the eye (?)

start at 40 sec xxx

SPACE TIME Fourier transform in time Fourier transform in space.

Signals and Systems EE235 Lecture 23 Leo Lam ©

Presentation transcript:

Fourier theory We know a lot about waves at a single  : n( , v p ( , R(  absorption(  … Analyze arbitrary in terms of these, because Fourier told us that…. How does a complicated optical pulse reflect off a surface?

Fourier Series Example f(t) c n or c(  )

Fourier Theory Summary Fourier Series: (f periodic or defined over (0,T) Fourier Transforms: (f nonperiodic, all time) with c n  c(  ) and m  0   Optic’s choice of sign for f(t):

Discrete vs continuous f(  )

Fourier Transform Example f(t) c n or c(  )

FTs you should get to know!

Gaussian Gaussian doesn’t have “ringing” in the FT!

Widths in t, 

“Uncertainty principle” in QM: related to time-frequency widths in waves 101 waves

Uncertainty principle E(t) N functions added, equally spaced in frequency 11 waves101 waves:  is much wider

Power spectrum 11 waves101 waves Inverse FT: Does the same power spectrum give the same f(t)? Power spectrum of cos, sin

Uncertainty principle 101 waves Why is it an inequality?

Importance of phase in f(  ) 11 waves101 waves Try: Linear phase function:  t  is the same. Pulse is shifted

Importance of phase 11 waves101 waves Try: Quadratic dependence:  t  is much bigger for the same 

Importance of phase 11 waves101 waves Random dependence:  t  is infinite (noise)  t  is much bigger for the same 

Summary: Importance of phase 11 waves101 waves Why is it an inequality? f(t) changes greatly with phase  The shortest is had only for  constant or linear. All others will make  comes entirely from |f(  )|, which has no phase information.

Carrier frequency-envelope principle 11 waves101 waves The FT f(  ) is the FT of ___ centered at ____. The width  is the width of ____ Optical pulses are often a steady (“carrier”) wave at multiplied by an envelope function

Which pulse f(t) will have f(  ) centered around the highest frequencies? a) b) c) Which f(t) will have the greatest width  in f(  ) around its central frequency? a) b) c)

Compare the “ringing” in the FT of rectangular pulse envelope triangular pulse envelope Gaussian pulse envelope sinc pulse envelope

Fourier theory

Fourier theory and delta functions