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'''Another special function is the circ function and the jinc function.'''
 
'''Another special function is the circ function and the jinc function.'''
*<math>circ(x,y)------------CSFT----------------jinc(u,v)</math>
+
*'''<math>circ(x,y)------------CSFT----------------jinc(u,v)</math>'''
  
 
*Notes: if we are trying to draw circ(x,y) from a top view, it will look like a circle with a radius of ½. In the 3D plot, we keep the top view as a base, making the height as 1. The plot is a cylinder.
 
*Notes: if we are trying to draw circ(x,y) from a top view, it will look like a circle with a radius of ½. In the 3D plot, we keep the top view as a base, making the height as 1. The plot is a cylinder.
  
 
*Other important transform pairs:
 
*Other important transform pairs:
 +
*Other representations of 2D signals:
 +
I will come back later!

Revision as of 12:50, 16 November 2009

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Spectral Analysis of 2D Signals (Nov.16)

This recitation covers the material from Nov. 4 to Nov. 13. So far, we have introduced the basic knowledge of 2D signals. As a review, let us start from the Continuous-Space Fourier Transform(CSFT) definitons and its inverse transform.

In 1D, we have:

  • $ X(f) = \int{x(t)e^{-j2pift} dt } $
  • $ x(t) = \int{X(2pif)e^{j2pift} df } $

Similarily, in2D, we have:

  • Forward transform- $ F(u,v) = \int{f(x,y)e^{-j2pi(ux+vy)} dxdy } $
  • Inverse transform- $ f(x,y) = \int{F(u,v)e^{j2pi(ux+vy)} dudv } $

Like 1D signals, properties such as the linearity, the shifting property, and so on, remained the same in 2D signals.

  • Linearity:$ af1(x,y)+bf2(x,y)------CSFT------ aF1(u,v)+bF2(u,v) $
  • Scaling:$ f(x/a,y/b)---------------CSFT--------|ab|F(au,bv) $
  • Shifting: $ f(x-xo,y-yo)------------CSFT-------F(u,v)e^{-j2pi(uxo+vyo)} $
  • Modulation:$ f(x,y)e^{j2pi(xuo+yvo)}------------CSFT---------F(u-uo,v-vo) $
  • Reciprocity:$ F(x,y)-----------------CSFT ------f(-u,-v) $
  • Parseval’s relation:$ \int{|f(x,y)|^2dxdy }=\int{|F(u,v)|^2dudv } $
  • Initial value: $ F(0,0)=\int{f(x,y)dxdy } $

Before we go to the important transform pairs, the separability is a very important property of 2D signals. It enables us to transform 2D signals to our familiar 1D signals.

Given,

 $ g(x)-----1-D CSFT-----------G(u) $
 $ h(y)----1-D  CSFT-----------H(v) $
 $ f(x,y)---2-D CSFT------------F(u,v) $

If a function can be rewritten as $ f(x,y)=g(x)h(y) $; then, its fourier transform is $ F(u,v)=G(u)H(v) $ .

  • For example, $ rect(x,y)=rect(x)rect(y)----------CSFT------------sinc(u)sinc(v)=sinc(u,v) $
  • Notes: If we are trying to draw rect(x,y) from a top view, it will just look like a square. In the 3D plot, keep the top view as a base, making the height as 1. The plot is a cube. Similar as sinc(u,v).

Another special function is the circ function and the jinc function.

  • $ circ(x,y)------------CSFT----------------jinc(u,v) $
  • Notes: if we are trying to draw circ(x,y) from a top view, it will look like a circle with a radius of ½. In the 3D plot, we keep the top view as a base, making the height as 1. The plot is a cylinder.
  • Other important transform pairs:
  • Other representations of 2D signals:

I will come back later!

Alumni Liaison

Ph.D. 2007, working on developing cool imaging technologies for digital cameras, camera phones, and video surveillance cameras.

Buyue Zhang