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A Challenging Example Male Pelvis –Bladder – Prostate – Rectum.

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Presentation on theme: "A Challenging Example Male Pelvis –Bladder – Prostate – Rectum."— Presentation transcript:

1 A Challenging Example Male Pelvis –Bladder – Prostate – Rectum

2 A Challenging Example Male Pelvis –Bladder – Prostate – Rectum –How do they move over time (days)? (all within same person)

3 A Challenging Example Male Pelvis –Bladder – Prostate – Rectum –How do they move over time (days)? –Critical to Radiation Treatment (cancer)

4 A Challenging Example Male Pelvis –Bladder – Prostate – Rectum –How do they move over time (days)? –Critical to Radiation Treatment (cancer) Work with 3-d CT (“Computed Tomography”, = 3d version of X-ray)

5 A Challenging Example Male Pelvis –Bladder – Prostate – Rectum –How do they move over time (days)? –Critical to Radiation Treatment (cancer) Work with 3-d CT –Very Challenging to Segment –Find boundary of each object? –Represent each Object?

6 Male Pelvis – Raw Data One CT Slice (in 3d image) Like X-ray: White = Dense (Bone) Black = Gas

7 Male Pelvis – Raw Data One CT Slice (in 3d image) Tail Bone

8 Male Pelvis – Raw Data One CT Slice (in 3d image) Tail Bone Rectum

9 Male Pelvis – Raw Data One CT Slice (in 3d image) Tail Bone Rectum Bladder

10 Male Pelvis – Raw Data One CT Slice (in 3d image) Tail Bone Rectum Bladder Prostate

11 Male Pelvis – Raw Data Bladder: manual segmentation Slice by slice Reassembled

12 Male Pelvis – Raw Data Bladder: Slices: Reassembled in 3d How to represent? Thanks: Ja-Yeon Jeong

13 Object Representation Landmarks (hard to find)

14 Object Representation Landmarks (hard to find) Boundary Rep’ns (no correspondence)

15 Object Representation Landmarks (hard to find) Boundary Rep’ns (no correspondence) Medial representations –Find “skeleton” –Discretize as “atoms” called M-reps

16 3-d m-reps Bladder – Prostate – Rectum (multiple objects, J. Y. Jeong) Medial Atoms provide “skeleton” Implied Boundary from “spokes”  “surface”

17 3-d m-reps M-rep model fitting Easy, when starting from binary (blue)

18 3-d m-reps M-rep model fitting Easy, when starting from binary (blue) But very expensive (30 – 40 minutes technician’s time) Want automatic approach

19 3-d m-reps M-rep model fitting Easy, when starting from binary (blue) But very expensive (30 – 40 minutes technician’s time) Want automatic approach Challenging, because of poor contrast, noise, … Need to borrow information across training sample

20 3-d m-reps M-rep model fitting Easy, when starting from binary (blue) But very expensive (30 – 40 minutes technician’s time) Want automatic approach Challenging, because of poor contrast, noise, … Need to borrow information across training sample Use Bayes approach: prior & likelihood  posterior (A surrogate for “atomical knowledge”)

21 3-d m-reps M-rep model fitting Easy, when starting from binary (blue) But very expensive (30 – 40 minutes technician’s time) Want automatic approach Challenging, because of poor contrast, noise, … Need to borrow information across training sample Use Bayes approach: prior & likelihood  posterior ~Conjugate Gaussians (Embarassingly Straightforward?)

22 3-d m-reps M-rep model fitting Easy, when starting from binary (blue) But very expensive (30 – 40 minutes technician’s time) Want automatic approach Challenging, because of poor contrast, noise, … Need to borrow information across training sample Use Bayes approach: prior & likelihood  posterior ~Conjugate Gaussians, but there are issues: Major HLDSS challenges Manifold aspect of data

23 3-d m-reps M-rep model fitting Very Successful Jeong (2009)

24 3-d m-reps M-rep model fitting Very Successful Jeong (2009) Basis of Startup Company: Morphormics

25 Mildly Non-Euclidean Spaces Statistical Analysis of M-rep Data Recall: Many direct products of: Locations Radii Angles

26 Mildly Non-Euclidean Spaces Statistical Analysis of M-rep Data Recall: Many direct products of: Locations Radii Angles I.e. points on smooth manifold

27 Mildly Non-Euclidean Spaces Statistical Analysis of M-rep Data Recall: Many direct products of: Locations Radii Angles I.e. points on smooth manifold Data in non-Euclidean Space But only mildly non-Euclidean

28 28 UNC, Stat & OR PCA for m-reps, II PCA on non-Euclidean spaces? (i.e. on Lie Groups / Symmetric Spaces)

29 29 UNC, Stat & OR PCA for m-reps, II PCA on non-Euclidean spaces? (i.e. on Lie Groups / Symmetric Spaces) T. Fletcher: Principal Geodesic Analysis (2004 UNC CS PhD Dissertation)

30 30 UNC, Stat & OR PCA for m-reps, II PCA on non-Euclidean spaces? (i.e. on Lie Groups / Symmetric Spaces) T. Fletcher: Principal Geodesic Analysis Idea: replace “linear summary of data” With “geodesic summary of data”…

31 31 UNC, Stat & OR PGA for m-reps, Bladder-Prostate-Rectum Bladder – Prostate – Rectum, 1 person, 17 days PG 1 PG 2 PG 3 (analysis by Ja Yeon Jeong)

32 32 UNC, Stat & OR PGA for m-reps, Bladder-Prostate-Rectum Bladder – Prostate – Rectum, 1 person, 17 days PG 1 PG 2 PG 3 (analysis by Ja Yeon Jeong)

33 33 UNC, Stat & OR PGA for m-reps, Bladder-Prostate-Rectum Bladder – Prostate – Rectum, 1 person, 17 days PG 1 PG 2 PG 3 (analysis by Ja Yeon Jeong)

34 34 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data

35 35 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean

36 36 UNC, Stat & OR PCA Extensions for Data on Manifolds

37 37 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean But Not In Non-Euclidean Spaces

38 38 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean Counterexample: Data on sphere, along equator

39 39 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean Extreme 3 Point Examples

40 40 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean Huckemann, Hotz & Munk (Geod. PCA)

41 41 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean Huckemann, Hotz & Munk (Geod. PCA) Best fit of any geodesic to data

42 42 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean Huckemann, Hotz & Munk (Geod. PCA) Best fit of any geodesic to data Counterexample: Data follows Tropic of Capricorn

43 43 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean Huckemann, Hotz & Munk (Geod. PCA) Best fit of any geodesic to data Jung, Foskey & Marron (Princ. Arc Anal.)

44 44 UNC, Stat & OR PCA Extensions for Data on Manifolds Fletcher (Principal Geodesic Anal.) Best fit of geodesic to data Constrained to go through geodesic mean Huckemann, Hotz & Munk (Geod. PCA) Best fit of any geodesic to data Jung, Foskey & Marron (Princ. Arc Anal.) Best fit of any circle to data (motivated by conformal maps)

45 45 UNC, Stat & OR PCA Extensions for Data on Manifolds

46 46 UNC, Stat & OR Principal Arc Analysis Jung, Foskey & Marron (2011) Best fit of any circle to data Can give better fit than geodesics

47 47 UNC, Stat & OR Principal Arc Analysis Jung, Foskey & Marron (2011) Best fit of any circle to data Can give better fit than geodesics Observed for simulated m-rep example

48 48 UNC, Stat & OR Challenge being addressed

49 49 UNC, Stat & OR Composite Nested Spheres

50 50 UNC, Stat & OR Landmark Based Shape Analysis Kendall Bookstein Dryden & Mardia (recall major monographs)

51 51 UNC, Stat & OR Landmark Based Shape Analysis Kendall Bookstein Dryden & Mardia Digit 3 Data

52 52 UNC, Stat & OR Landmark Based Shape Analysis Kendall Bookstein Dryden & Mardia Digit 3 Data

53 53 UNC, Stat & OR Landmark Based Shape Analysis Kendall Bookstein Dryden & Mardia Digit 3 Data (digitized to 13 landmarks)

54 54 UNC, Stat & OR Landmark Based Shape Analysis Key Step: mod out Translation Scaling Rotation

55 55 UNC, Stat & OR Landmark Based Shape Analysis Key Step: mod out Translation Scaling Rotation Result: Data Objects   points on Manifold ( ~ S 2k-4 )

56 56 UNC, Stat & OR Landmark Based Shape Analysis Currently popular approaches to PCA on S k :  Early: PCA on projections (Tangent Plane Analysis)

57 57 UNC, Stat & OR Landmark Based Shape Analysis Currently popular approaches to PCA on S k :  Early: PCA on projections  Fletcher: Geodesics through mean

58 58 UNC, Stat & OR Landmark Based Shape Analysis Currently popular approaches to PCA on S k :  Early: PCA on projections  Fletcher: Geodesics through mean  Huckemann, et al: Any Geodesic

59 59 UNC, Stat & OR Landmark Based Shape Analysis Currently popular approaches to PCA on S k :  Early: PCA on projections  Fletcher: Geodesics through mean  Huckemann, et al: Any Geodesic New Approach: Principal Nested Sphere Analysis Jung, Dryden & Marron (2012)

60 60 UNC, Stat & OR Principal Nested Spheres Analysis Main Goal: Extend Principal Arc Analysis (S 2 to S k )

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