Presentation is loading. Please wait.

Presentation is loading. Please wait.

Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 1 Anisotropic Diffusion’s Extension to Constrained Line Processes  Anisotropic.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 1 Anisotropic Diffusion’s Extension to Constrained Line Processes  Anisotropic."— Presentation transcript:

1 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 1 Anisotropic Diffusion’s Extension to Constrained Line Processes  Anisotropic Diffusion’s Application in 3D Confocal Microscopy Image Processing Cédric Dufour

2 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 2 Contents  Anisotropic diffusion’s basics  Extension to constrained line processes  Anisotropic diffusion vs. constrained line processes  3D microscopy image processing  Conclusions

3 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 3 Anisotropic diffusion’s basics (1)  Underlying principle: standard heat diffusion Grayscale intensity value Time (iteration) variable Diffusion coefficient  Equivalent to gaussian local meaning  Equivalent to gaussian local meaning (the variance being related unequivocally to the diffusion coefficient)

4 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 4 Anisotropic diffusion’s basics (2)  Problem: diffusion occurs in all direction, regardless of edges  Blurring

5 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 5 Anisotropic diffusion’s basics (3)  Solution: bind the diffusion coefficient to the gradient of the intensity Anisotropic diffusion coefficient (“edge stopping” function)  Care must be taken in the choice of the edge stopping function for the problem to be well-posed More info: edge stopping function

6 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 6 Anisotropic diffusion’s basics (4)  Results: diffusion is inhibited when the gradient gets more important (edges)  Piecewise smooth image A.D.

7 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 7 Extension to constrained line processes (1)  Anisotropic diffusion can be derived from the minimization of a smoothness functional: Smoothness normSmoothness functional More info: 3D neighborhood for anisotropic diffusion

8 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 8 Extension to constrained line processes (2)  Expressing this minimization problem according to the line process formulation, we have: Fitting constantLine process penalty function Line process  Adding explicit spatial constraints: Spatial constraints More info: line process and penalty function characteristics

9 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 9 Extension to constrained line processes (3)  The line process formulation is related to the standard anisotropic formulation through: More info: starting relating axiom between the standard anisotropic formulation and the line process formulation

10 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 10 Extension to constrained line processes (4)  Computational results: ImageGradient

11 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 11 Extension to constrained line processes (5)  Adding spatial constraints...  … we obtain the following iterative formula: More info: spatial constraints clique Hysteresis termNon-maximum suppression term

12 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 12 Extension to constrained line processes (6)  Results: the diffusion is inhibited by the spatial constraints  Sharper details and smoother contours C.L.P.

13 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 13 Anisotropic diffusion vs. constrained line processes (7)  Comparative MSE and variance: MSEVariance A.D. C.L.P. A.D. C.L.P.

14 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 14

15 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 15 3D microscopy image processing (1)  Goal: obtain correlation statistics in multi-channel 3D confocal microscopy images CH.1CH.2

16 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 16 3D microscopy image processing (2)  Step 1: de-noising (using anisotropic diffusion)  Smooth image CH.1CH.2

17 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 17 3D microscopy image processing (3)  Step 2: thresholding  Proteins mask CH.1CH.2

18 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 18 3D microscopy image processing (4)  Step 3: skeleton and labeling  Disjointed protein labeled skeleton CH.1CH.2 More info: disjointed clusters

19 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 19 3D microscopy image processing (5)  Step 4: geodesic growth  Disjointed protein labeled mask CH.1CH.2

20 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 20 3D microscopy image processing (6)  Step 5: compute distance table  Distance between proteins CH.1  CH.2

21 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 21 3D microscopy image processing (7)  Step 6: clustering  Group proteins according to the separating distance D = 5 x ‘mean size’D = 7.5 x ‘mean size’

22 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 22 3D microscopy image processing (8)  Step 7: compute the statistics  Proper correlation statistics and interpretation To do! (IBCM’s biologists task)

23 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 23 Conclusions  Anisotropic diffusion is a powerful tool for de-noising  Spatial constraints (added through the line process formulation) allow to obtain better quality denoising  Application of the anisotropic diffusion along with other morphological and clustering tools allowed efficient segmentation and classification of proteins appearing in 3D confocal microscopy images.

24 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 24 Thank you for your attention !

25 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 25 More info (1)  Edge stopping function (here, Lorenzian): Lorenzian (  =0.25)

26 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 26 More info (2)  3D neighborhood for anisotropic diffusion:

27 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 27 More info (3)  Line process and penalty function characteristics: Lorenzian (  =0.25)

28 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 28 More info (4)  Starting relating axiom between the standard anisotropic formulation and the line process formulation:

29 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 29 More info (5)  Spatial constraints clique:

30 Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 30 More info (6)  Step 3: skeleton and labeling  Disjointed clusters Original clusterDisjointed cluster

Download ppt "Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 1 Anisotropic Diffusion’s Extension to Constrained Line Processes  Anisotropic."

Similar presentations

Active Appearance Models

Active Appearance Models
Level set based Image Segmentation Hang Xiao Jan12, 2013.

Level set based Image Segmentation Hang Xiao Jan12, 2013.
Boundary Detection - Edges Boundaries of objects –Usually different materials/orientations, intensity changes.

Boundary Detection - Edges Boundaries of objects –Usually different materials/orientations, intensity changes.
Active Contours, Level Sets, and Image Segmentation

Active Contours, Level Sets, and Image Segmentation
Lecture 6 Sharpening Filters

Lecture 6 Sharpening Filters
Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 1 Supercomputers and client-server environment for biomedical image processing.

Signal Processing Laboratory Swiss Federal Institute of Technology, Lausanne 1 Supercomputers and client-server environment for biomedical image processing.
Digital Image Processing

Digital Image Processing
Digital Image Processing In The Name Of God Digital Image Processing Lecture3: Image enhancement M. Ghelich Oghli By: M. Ghelich Oghli

Digital Image Processing In The Name Of God Digital Image Processing Lecture3: Image enhancement M. Ghelich Oghli By: M. Ghelich Oghli
電腦視覺 Computer and Robot Vision I Chapter2: Binary Machine Vision: Thresholding and Segmentation Instructor: Shih-Shinh Huang 1.

電腦視覺 Computer and Robot Vision I Chapter2: Binary Machine Vision: Thresholding and Segmentation Instructor: Shih-Shinh Huang 1.
Image Segmentation some examples Zhiqiang wang zwang22@kent.edu.

Image Segmentation some examples Zhiqiang wang
Image Segmentation and Active Contour

Image Segmentation and Active Contour
On Constrained Optimization Approach To Object Segmentation Chia Han, Xun Wang, Feng Gao, Zhigang Peng, Xiaokun Li, Lei He, William Wee Artificial Intelligence.

On Constrained Optimization Approach To Object Segmentation Chia Han, Xun Wang, Feng Gao, Zhigang Peng, Xiaokun Li, Lei He, William Wee Artificial Intelligence.
Signal Processing Institute Swiss Federal Institute of Technology, Lausanne 1 Feature selection for audio-visual speech recognition Mihai Gurban.

Signal Processing Institute Swiss Federal Institute of Technology, Lausanne 1 Feature selection for audio-visual speech recognition Mihai Gurban.
Edge detection Goal: Identify sudden changes (discontinuities) in an image Intuitively, most semantic and shape information from the image can be encoded.

Edge detection Goal: Identify sudden changes (discontinuities) in an image Intuitively, most semantic and shape information from the image can be encoded.
Image Filtering CS485/685 Computer Vision Prof. George Bebis.

Image Filtering CS485/685 Computer Vision Prof. George Bebis.
Canny Edge Detector.

Canny Edge Detector.
EE565 Advanced Image Processing Copyright Xin Li 20081 Different Frameworks for Image Processing Statistical/Stochastic Models: Wiener’s MMSE estimation.

EE565 Advanced Image Processing Copyright Xin Li Different Frameworks for Image Processing Statistical/Stochastic Models: Wiener’s MMSE estimation.
Edge detection Goal: Identify sudden changes (discontinuities) in an image Intuitively, most semantic and shape information from the image can be encoded.

Edge detection Goal: Identify sudden changes (discontinuities) in an image Intuitively, most semantic and shape information from the image can be encoded.
Advanced Image Processing Image Relaxation – Restoration and Feature Extraction 02/02/10.

Advanced Image Processing Image Relaxation – Restoration and Feature Extraction 02/02/10.
Image Denoising using Wavelet Thresholding Techniques Submitted by Yang 9024553282.

Image Denoising using Wavelet Thresholding Techniques Submitted by Yang

Similar presentations

Ads by Google