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EE 638: Principles of Digital Color Imaging Systems

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Presentation on theme: "EE 638: Principles of Digital Color Imaging Systems"— Presentation transcript:

1 EE 638: Principles of Digital Color Imaging Systems
Lecture 20: 2-D Linear Systems and Spectral Analysis

2 Synopsis Special 2-D Signals
2-D Continuous-space Fourier Transform (CSFT) Linear, Shift-invariant Imaging Systems Periodic Structures Resources: My ECE 438 course materials ( – see lecture notes, both legacy and published versions) Prof. Bouman’s ECE 637 course materials

3 Special 2-D Signals

4 (Bassel function of 1st kind order 1)

5 2-D Impulse Function

6 Sifting Property

7 Spatial Frequency Components

8 Spatial Domain Frequency Domain

9 2-D CSFT Forward Transform: Inverse Transform:

10 Hermitian Symmetry for Real Signals
Let If f(x,y) is real, In this case, the inverse transform may be written as

11 2-D Transform Relations
1. linearity 2. Scaling and shifting 3. Modulation 4. Reciprocity 5. Parseval’s Relation

12 6. Initial value 7. Let then

13 Separability A function is separable if it factors as:
Some important separable functions:

14 Important Transform Pairs
1. 2. 3. 4. 5. 6. (by shifting property) (by reciprocity) (by modulation property)

15 7. 8.

16 Linear, Shift-invariant(LSIV) Image System

17 Imaging an Extended Object
System Imaging System (by homogeneity)

18 diffraction limited image Image predicted by geometrical optics
By superposition, This type of analysis extends to a very large class of imaging systems. diffraction limited image Image predicted by geometrical optics 2-D convolution integral

19 CSFT and LSIV Imaging Systems Convolution Theorem
As in the 1-D case, we have the following identity for any functions and , Consider the image of a complex exponential object: Imaging System is an eigenfunction of the system

20 Now consider again the extended object:
By linearity: Imaging System

21 Convolution & Product Theorem
Since and are arbitrary signals, we have the following Fourier transform relation or By reciprocity, we also have the following result

22 Impulse Function Impulse function is separable: Shifting property

23 Comb and Replication Operators
Transform relation

24 Periodic Structures – Example 1
Zero crossing point at 1/A Impulse sheet like function

25 Periodic Structures – Example 2

26 Derivation Should be v, not nu, and u, not mu

27 Periodic Structures – Example 3

28 Periodic Structures – Example 4

29 Periodic Structures – Example 5

30 Example: Digital Camera
Input image: Output image (looking through a mesh): Sensing area arbitrary

31 How to reconstruct the image?
constant Interchange summation and convolution  convolution with impulse  shifting I to (k/X, l/X)

32 Use low-pass filter with cut-off frequency of
in frequency domain Low-pass Filter DSFT Inv-DSFT Reconstructed Image

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