1 / 21

Digital Image Processing Lecture 20: Representation & Description

Digital Image Processing Lecture 20: Representation & Description. Prof. Charlene Tsai. * Materials from Gonzales chapter 11. Representation. After segmentation, we get pixels along the boundary or pixels contained in a region. Representing a region involves two choices:

arkadiy-popov
Télécharger la présentation

Digital Image Processing Lecture 20: Representation & Description

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Digital Image Processing Lecture 20: Representation & Description Prof. Charlene Tsai * Materials from Gonzales chapter 11

  2. Representation • After segmentation, we get pixels along the boundary or pixels contained in a region. • Representing a region involves two choices: • Using external characteristics, e.g. boundary • Using internal characteristics, e.g. color and texture

  3. Common Representation • Common external representation methods are: • Chain code • Polygonal approximation • Signature • Boundary segments • Skeleton (medial axis) • We’ll discuss the first 3.

  4. Method 1: Chain Codes • Represent a boundary by a connected sequence of straight-line segments of specified length and direction. • Directions are coded using the numbering scheme 4-connectivity 8 connectivity

  5. Generation of Chain Codes • Walking along the boundary in clockwise direction, for every pair of pixels assign the direction. • Problems: • Long chain • Sensitive to noise • Remedies? • Resampling using larger grid spacing.

  6. Resampling for Chain Codes 0766…12 (8-directional) 0033…01 (4-directional) Spacing of the sampling grid affect the accuracy of the representation

  7. Normalization for Chain Codes • With respect to starting point: • Make the chain code a circular sequence • Redefine the starting point which gives an integer of minimum magnitude • E.g. 101003333222 normalized to 003333222101 • For rotation: • Using first difference (FD) obtained by counting the number of direction changes in counterclockwise direction • E.g FD of a 4-direction chain code 10103322 is 3133030 • For scaling: • Altering the size of the resampling grid.

  8. Method 2: Polygonal Approximation • Approximate a digital boundary with arbitrary accuracy by a polygon. • Goal: to capture the “essence” of the boundary shape with the fewest possible polygonal segments.

  9. Minimum Perimeter Polygons • Two techniques: merging & splitting

  10. Merging Technique • Repeat the following steps: • Merging unprocessed points along the boundary until the least-square error line fit exceed the threshold. • Store the parameters of the line • Reset the LS error to 0 • Intersections of adjacent line segments form vertices of the polygon. • Problem: vertices of the polygon do not always correspond to inflections (e.g. corners) in the original boundary.

  11. Splitting Technique • Subdivide a segment successively into two parts until a specified criterion is met. • For example

  12. Method 3: Signature • Reduce the boundary representation to a 1D function • For example, distance vs. angle

  13. (con’d) • For the signature just described • Invariant to translation (everything w.r.t. the centroid) • Depending on rotation and scaling • How to remove the dependence on rotation? • Selecting point farthest from the centroid • Farthest point on the eigen axis (more robust) • Using the chain code • How to remove the dependence on scaling? • Scale all functions to span the range, say, [0,1] (not very robust) • Normalize by the variance

  14. Descriptors • Boundary information can be used directly, or converted into features that describe properties of a region, such as • Length of the boundary • Orientation of straight line joining its extreme points • Number of concavities in the boundary

  15. Boundary Descriptors (Properties) • Length: approximated by the # of pixels • Diameter: • Basic rectangle: defined by • Major axis: the line giving the diameter • Minor axis: the line perpendicular to major axis • Eccentricity: ratio of the 2 axes

  16. Fourier Descriptor • Given a set of boundary points (x0, y0), (x1, y1), (x2, y2), …,. (xK-1, yK-1). • Represent the sequence of coordinates as s(k)=[xk, yk], for k=0, 1, 2, …, K-1. • Using complex representation for each point: s(k) = xk + jyk • Advantage: reducing 2D to 1D problem

  17. 1D Fourier (Review) • DFT of s(k) is • The complex coefficients a(u), for u=0,1, 2, …, K-1, are called the Fourier descriptor of the boundary • The inverse Fourier restores s(k)

  18. Fourier Approximation • Using only the first P coefficients (a(u)=0 for u>P) • Please note that k still ranges from 0 to K-1 • The smaller P becomes, the more detail that is lost on the boundary • There are ways to make the descriptor insensitive to translation, rotation, and scale changes. Please refer to Gonzalez pg 658-659 for details.

  19. Example

  20. Region Descriptors • Simple descriptors: • Area: # of pixels in the region • Perimeter: length of its boundary • Compactness: (perimeter)2/area • Q: What shape gives the minimal compactness • Mean and median of the gray levels. • Topological descriptors: • # of holes • # of connected components

  21. Summary • Common external representation methods are: • Chain code • Polygonal approximation • Signature • Descriptors • Boundary descriptor • Fourier descriptor • Region descriptor

More Related