Download presentation
Presentation is loading. Please wait.
1
1 UNC, Stat & OR Place Name OODA of Tree Structured Objects J. S. Marron Dept. of Statistics and Operations Research October 2, 2016
2
2 UNC, Stat & OR Object Oriented Data Analysis What is the “atom” of a statistical analysis? First Course: Numbers Multivariate Analysis: Vectors Functional Data Analysis: Curves OODA: More Complicated Objects Images Movies Shapes Tree Structured Objects
3
3 UNC, Stat & OR Euclidean Data Spaces Data are vectors, in Effective (and Traditional) Analysis: Linear Methods Mean Covariance Principal Component Analysis Gaussian Distribution
4
4 UNC, Stat & OR Euclidean Data Spaces Data are vectors, in Challenges: High Dimension, Low Sample Size (Classical Methods Fail) Visualization: Find Structure (Expected & Unknown) Understand range of “normal cases” Find anomalies
5
5 UNC, Stat & OR Euclidean Data - Visualization
6
6 UNC, Stat & OR Euclidean Data - Visualization
7
7 UNC, Stat & OR Non - Euclidean Data Spaces “Simple” Example: m-reps for shapes Data involve angles Thus lie in “manifold” i.e. “curved feature space” Typical Approach: Tangent Plane Approx. e.g. PGA Personal Terminology: “Mildly non-Euclidean”
8
8 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)
9
9 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)
10
10 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)
11
11 UNC, Stat & OR Non - Euclidean Data Spaces What is “Strongly Non-Euclidean” Case? Trees as Data Special Challenge: No Tangent Plane Must Re-Invent Data Analysis
12
12 UNC, Stat & OR Strongly Non-Euclidean Spaces Trees as Data Objects From Graph Theory: Graph is set of nodes and edges Tree has root and direction Data Objects: set of trees
13
13 UNC, Stat & OR Strongly Non-Euclidean Spaces Motivating Example: From Dr. Elizabeth BullittDr. Elizabeth Bullitt Dept. of Neurosurgery, UNC Blood Vessel Trees in Brains Segmented from MRAs Study population of trees Forest of Trees
14
14 UNC, Stat & OR Blood vessel tree data The tree team: Very Interdsciplinary Neurosurgery: Bullitt, Ladha Statistics: Wang, Marron Optimization: Aydin, Pataki
15
15 UNC, Stat & OR Blood vessel tree data Marron’s brain: MRI view Single Slice From 3-d Image
16
16 UNC, Stat & OR Blood vessel tree data Marron’s brain: MRA view “A” for Angiography” Finds blood vessels (show up as white) Track through 3d
17
17 UNC, Stat & OR Blood vessel tree data Marron’s brain: MRA view “A” for Angiography” Finds blood vessels (show up as white) Track through 3d
18
18 UNC, Stat & OR Blood vessel tree data Marron’s brain: MRA view “A” for Angiography” Finds blood vessels (show up as white) Track through 3d
19
19 UNC, Stat & OR Blood vessel tree data Marron’s brain: MRA view “A” for Angiography” Finds blood vessels (show up as white) Track through 3d
20
20 UNC, Stat & OR Blood vessel tree data Marron’s brain: MRA view “A” for “Angiography” Finds blood vessels (show up as white) Track through 3d
21
21 UNC, Stat & OR Blood vessel tree data Marron’s brain: MRA view “A” for Angiography” Finds blood vessels (show up as white) Track through 3d
22
22 UNC, Stat & OR Blood vessel tree data Marron’s brain: From MRA Segment tree of vessel segments Using tube tracking Bullitt and Aylward (2002)
23
23 UNC, Stat & OR Blood vessel tree data Marron’s brain: From MRA Reconstruct trees in 3d Rotate to view
24
24 UNC, Stat & OR Blood vessel tree data Marron’s brain: From MRA Reconstruct trees in 3d Rotate to view
25
25 UNC, Stat & OR Blood vessel tree data Marron’s brain: From MRA Reconstruct trees in 3d Rotate to view
26
26 UNC, Stat & OR Blood vessel tree data Marron’s brain: From MRA Reconstruct trees in 3d Rotate to view
27
27 UNC, Stat & OR Blood vessel tree data Marron’s brain: From MRA Reconstruct trees in 3d Rotate to view
28
28 UNC, Stat & OR Blood vessel tree data Marron’s brain: From MRA Reconstruct trees in 3d Rotate to view
29
29 UNC, Stat & OR Blood vessel tree data Now look over many people (data objects) Structure of population (understand variation?) PCA in strongly non-Euclidean Space???,...,,
30
30 UNC, Stat & OR Blood vessel tree data Examples of Potential Specific Goals (not accessible by traditional methods) Predict Stroke Tendency (Collateral Circulation) Screen for Loci of Pathology Explore how age affects connectivity,...,,
31
31 UNC, Stat & OR Blood vessel tree data Big Picture: 3 Approaches 1.Purely Combinatorial 2.Euclidean Orthant 3.Harris Correspondence
32
32 UNC, Stat & OR Blood vessel tree data Big Picture: 3 Approaches 1.Purely Combinatorial 2.Euclidean Orthant 3.Harris Correspondence
33
33 UNC, Stat & OR Blood vessel tree data Possible focus of analysis: Connectivity structure only (topology) Location, size, orientation of segments Structure within each vessel segment,...,,
34
34 UNC, Stat & OR Blood vessel tree data Present Focus: Topology only Already challenging Later address additional challenges By adding attributes (locations, thicknesses, curvature, …) To tree nodes And extend analysis
35
35 UNC, Stat & OR Blood vessel tree data Topological Representation: Each Vessel Segment (up to 1 st Split) is a node Split Segments are child nodes Connecting lines show relationship
36
36 UNC, Stat & OR Blood vessel tree data Correspondence (which node on left???): I.Vessel Thickness Larger Median Radius on Left
37
37 UNC, Stat & OR Blood vessel tree data Recall from above: Marron’s brain: Focus on back Connectivity (topology) only (also consider right & left)
38
38 UNC, Stat & OR Blood vessel tree data Present Focus: Topology only Raw data as trees Marron’s reduced tree Back tree only
39
39 UNC, Stat & OR Blood vessel tree data Topology only E.g. Back Trees Full Population Study as movie Understand variation?
40
40 UNC, Stat & OR Blood vessel tree data Correspondence (which node on left???): I.Vessel Thickness Larger Median Radius on Left II.Descendants Most Descendants on Left
41
41 UNC, Stat & OR Blood vessel tree data Marron’s Back Thickness Descendant Trees Look Similar
42
42 UNC, Stat & OR Blood vessel tree data Case 34 Back Thickness Descendant Trees Quite Different
43
43 UNC, Stat & OR Blood vessel tree data Whole Population – Thickness Correspondence
44
44 UNC, Stat & OR Blood vessel tree data Whole Population – Descendant Correspondence
45
45 UNC, Stat & OR Graphical Concept: Support Tree The union of all trees in data set T. Consists of the nodes that exist in T and their “weights”. Weight of a node, w(v,T) is the number of trees it occurs in the data set. Use to compare Thickness & Descendant Correspences
46
46 UNC, Stat & OR Support Tree Example Data trees: Support tree:
47
47 UNC, Stat & OR Graphical Concept: Support Tree Thickness: More Spread Descendant: More Compact
48
48 UNC, Stat & OR Graphical Concept: Support Tree Comparison of Correspondences: Thickness Corr. gives bushier trees (shows more population structure) Descendant Corr. suggests compact rep’n (easier to decompose, e.g. “PCA”?)
49
49 UNC, Stat & OR Strongly Non-Euclidean Spaces Statistics on Population of Tree-Structured Data Objects? Mean??? Analog of PCA??? Strongly non-Euclidean, since: Space of trees not a linear space Not even approximately linear (no tangent plane)
50
50 UNC, Stat & OR Mildly Non-Euclidean Spaces Useful View of Manifold Data: Tangent Space Center: Frech é t Mean Reason for terminology “ mildly non Euclidean ”
51
51 UNC, Stat & OR Strongly Non-Euclidean Spaces Mean of Population of Tree-Structured Data Objects? Natural approach: Fr é chet mean Requires a metric (distance) on tree space
52
52 UNC, Stat & OR Strongly Non-Euclidean Spaces Appropriate metrics on tree space: Wang and Marron (2007) Depends on: Tree structure And nodal attributes Won ’ t go further here But gives appropriate Fr é chet mean
53
53 UNC, Stat & OR Strongly Non-Euclidean Spaces Appropriate metrics on tree space: Wang and Marron (2007) For topology only (studied here): Use Hamming Distance Just number of nodes not in common Gives appropriate Fr é chet mean
54
54 UNC, Stat & OR Hamming Distance The number of nodes in the symmetric difference of two trees. An example:
55
55 UNC, Stat & OR Hamming Distance The two trees drawn on top of each other: Common nodes: 2 Nodes only in blue tree: 4 Nodes only in red tree: 2 So, distance: 4+2=6
56
56 UNC, Stat & OR Strongly Non-Euclidean Spaces PCA on Tree Space? Recall Conventional PCA: Directions that explain structure in data Data are points in point cloud 1-d and 2-d projections allow insights about population structure
57
57 UNC, Stat & OR Illust’n of PCA View: PC1 Projections
58
58 UNC, Stat & OR Illust’n of PCA View: Projections on PC1,2 plane
59
59 UNC, Stat & OR PCA view: Lung Cancer Microarray Data
60
60 UNC, Stat & OR Source Batch Adj: PC 1-3 & DWD direction
61
61 UNC, Stat & OR Source Batch Adj: DWD Source Adjustment
62
62 UNC, Stat & OR Strongly Non-Euclidean Spaces PCA on Tree Space? Key Idea (Jim Ramsay): Replace 1-d subspace that best approximates data By 1-d representation that best approximates data Wang and Marron (2007) define notion of Treeline (in structure space)
63
63 UNC, Stat & OR Strongly Non-Euclidean Spaces PCA on Tree Space: Treeline Best 1-d representation of data Basic idea: From some starting tree Grow only in 1 “direction”
64
64 UNC, Stat & OR Definition of Tree-Line A set of trees, L, such that: L={u 0,u 1,u 2,…,u m } u i can be obtained by adding a single node (v i ) to u i-1 v i+1 is a child of vi Also, we will call the set of nodes hanged to u 0 as Path(L), path of treeline L: Path(L) = u m /u 0
65
65 UNC, Stat & OR Definition of Projection of a data tree t i onto treeline L is the closest point on L to the data tree:
66
66 UNC, Stat & OR Suppose we have the data tree: And the treeline: Example of projection Which point on the treeline is the closest to the data tree?
67
67 UNC, Stat & OR Example of projection u 0 : d(u 0,t) = 6
68
68 UNC, Stat & OR Example of projection u 0 : d(u 0,t) = 6 u 1 : d(u 1,t)=5
69
69 UNC, Stat & OR Example of projection u 0 : d(u 0,t) = 6 u 1 : d(u 1,t)=5 u 2 : d(u 2,t)=4
70
70 UNC, Stat & OR Example of projection u 0 : d(u 0,t) = 6 u 1 : d(u 1,t)=5 u 2 : d(u 2,t)=4 u 3 : d(u 3,t)=5
71
71 UNC, Stat & OR Example of projection u 0 : d(u 0,t) = 6 u 1 : d(u 1,t)=5 u 2 : d(u 2,t)=4 u 3 : d(u 3,t)=5 Closest!
72
72 UNC, Stat & OR Example of projection So, P L (t)=u 2 in this case Observation: Projection onto the treeline is u 0 combined with the members of P(L) that are in the data tree: The data tree: Its projection:
73
73 UNC, Stat & OR Example of projection Useful statistical summary: Score Length of Projection (analog of PC in PCA) Above Example: Score (~PCA Coeff.) for this tree = 3 The data tree:Its projection:
74
74 UNC, Stat & OR Best Tree Line The treeline that gives the smallest sum of distances:
75
75 UNC, Stat & OR Strongly Non-Euclidean Spaces PCA on Tree Space: Treeline Best 1-d representation of data Problem: Hard to compute In particular: to solve optimization problem Wang and Marron (2007) Maximum 4 vessel trees Hard to tackle serious trees (e.g. blood vessel trees)
76
76 UNC, Stat & OR Strongly Non-Euclidean Spaces PCA on Tree Space: Treeline Problem: Hard to compute Solution: Burcu Aydin & Gabor Pataki (linear time algorithm) (based on clever “reformulation” of problem)
77
77 UNC, Stat & OR PCA for blood vessel tree data PCA on Tree Space: Treelines Interesting to compare: Population of Left Trees Population of Right Trees Population of Back Trees And to study 1 st, 2 nd, 3 rd & 4 th treelines
78
78 UNC, Stat & OR PCA for blood vessel tree data Study “Directions” 1, 2, 3, 4 For sub- populations B, L, R (Thickness)
79
79 UNC, Stat & OR PCA for blood vessel tree data Notes on Treeline Directions: PC1 always to left BACK has most variation to right (PC2) LEFT has more varia’n to 2 nd level (PC2) RIGHT has more var’n to 1 st level (PC2) See these in the data?
80
80 UNC, Stat & OR PCA for blood vessel tree data (Thickness) Notes: PC1 - left BACK - right LEFT 2 nd lev RIGHT 1 st lev See these??
81
81 UNC, Stat & OR PCA for blood vessel tree data Revisit PC “Directions” (Thickness Corr.) Compare to Descendant?
82
82 UNC, Stat & OR PCA for blood vessel tree data Descendant Corr. - Similar Lessons - But Effects Stronger - Better Repres’n?
83
83 UNC, Stat & OR PCA for blood vessel tree data (Descendant) Notes: PC1 - left BACK - right LEFT 2 nd lev RIGHT 1 st lev See stronger Lessons?
84
84 UNC, Stat & OR Strongly Non-Euclidean Spaces PCA on Tree Space: Treeline Next represent data as projections Define as closest point in tree line (same as Euclidean PCA) Have corresponding score (length of projection along line) And analog of residual (distance from data point to projection)
85
85 UNC, Stat & OR PCA for blood vessel tree data Raw Data & Treelines, PC1, PC2, PC3:
86
86 UNC, Stat & OR PCA for blood vessel tree data Raw Data & Treelines, PC1, PC2, PC3: Projections, Scores, Residuals
87
87 UNC, Stat & OR PCA for blood vessel tree data Raw Data & Treelines, PC1, PC2, PC3: Cumulative Scores, Residuals
88
88 UNC, Stat & OR PCA for blood vessel tree data Individual (each PC separately) Scores Plot
89
89 UNC, Stat & OR PCA for blood vessel tree data Identify this person
90
90 UNC, Stat & OR PCA for blood vessel tree data Identify this person PC Scores: 8,9,3,5
91
91 UNC, Stat & OR PCA for blood vessel tree data Identify this person (PC Scores: 8,9,3,5): Red = older 0 = Female Note: color ~ age
92
92 UNC, Stat & OR PCA for blood vessel tree data Identify this person (PC Scores: 8,9,3,5): Red = older 0 = Female Note: color ~ age
93
93 UNC, Stat & OR PCA for blood vessel tree data Identify this person (PC scores 1,10,1,1)
94
94 UNC, Stat & OR PCA for blood vessel tree data Identify this person (PC scores 1,10,1,1)
95
95 UNC, Stat & OR PCA for blood vessel tree data Explain strange (low score) correlation?
96
96 UNC, Stat & OR PCA for blood vessel tree data Explain strange (low score) correlation? Revisit Treelines: Small PC1 Score Small PC3 Score Small PC1 Score Small PC4 Score
97
97 UNC, Stat & OR PCA for blood vessel tree data Individual (each PC sep’ly) Residuals Plot
98
98 UNC, Stat & OR PCA for blood vessel tree data Individual (each PC sep’ly) Residuals Plot Very strongly correlated Shows much variation not explained by PCs (data are very rich) Note age coloring useful Younger (bluer) more variation Older (redder) less variation
99
99 UNC, Stat & OR PCA for blood vessel tree data Important Data Analytic Goals: Understand impact of age (colors) Understand impact of gender (symbols) Understand handedness (too few) Understand ethnicity (too few) See these in PCA?
100
100 UNC, Stat & OR PCA for blood vessel tree data Data Analytic Goals: Age, Gender See these? No…
101
101 UNC, Stat & OR PCA for blood vessel tree data Alternate View: Cumulative Scores
102
102 UNC, Stat & OR PCA for blood vessel tree data Alternate View: Cumulative Scores Always below 45 degree line Better separation of age or gender? (doesn’t seem like it) This makes it easy to find: Best represented case Worst represented case
103
103 UNC, Stat & OR PCA for blood vessel tree data Cum. Scores: Best repr’ed case (10,19,20)
104
104 UNC, Stat & OR PCA for blood vessel tree data Cum. Scores: Best repr’ed case (10,19,20) PC1 & PC2 Scores Very Large
105
105 UNC, Stat & OR PCA for blood vessel tree data Cum. Scores: Worst repr’ed case (3,5,6)
106
106 UNC, Stat & OR PCA for blood vessel tree data Cum. Scores: Worst repr’ed case (3,5,6) Fairly small tree Growth in unusual directions
107
107 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores
108
108 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores Thickness Corr. does not show much Could look deeper, with linear fits What about Descendants Corr.???
109
109 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores - Descendants - PC1 all 11s - PC2 spread - PC3 4 or 11 - Corr. w/ Age?
110
110 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores Take Deeper Look By Fitting Lines And doing Hypotest of H 0 : slope = 0 Show p-values to assess significance Compare Thickness & Descendants Corr.
111
111 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores PC1 Only - Thickness Not Sig’t - Descendants Not Diverse
112
112 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores PC1 + PC2 - Thickness Not Sig’t - Descendants Left Sig’t
113
113 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores PC1 + 2 + 3 - Thickness Not Sig’t - Descendants Left Sig’t (less so)
114
114 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores PC1+2+3+4 - Thickness Not Sig’t - Descendants Left Sig’t (again less so)
115
115 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores PC2 only - Thickness Not Sig’t - Descendants Left Sig’t (again strong)
116
116 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores PC3 only - Thickness Not Sig’t - Descendants Not Sig’t (Only PC2?)
117
117 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores PC4 only - Thickness Back Sig’t? - Descendants Not Sig’t (Only PC2?)
118
118 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores Conclusions: - No Strong Age Connection - Significant Connection for: - Descendants - Left - PC2
119
119 UNC, Stat & OR PCA for blood vessel tree data Directly study age PC scores Explanation? - Difference in age is here? - Only for Descendants?
120
120 UNC, Stat & OR PCA for blood vessel tree data Overall Assessment of Tree-Line PCA Somewhat finds desired aspects (e.g. age effects) Descendant corr. better than thickness But representation seems too sparse (PCs not explaining enough variation) Need to improve notion of 1-d representation
121
121 UNC, Stat & OR Upcoming New Approach Replace Tree-Lines by Tree-Curves: Goal: Explain more variation Approach: Start at a tree (root for now) Sequentially add nodes (now can add anywhere) End at Support Tree Find: Best Fitting Tree Curve
122
122 UNC, Stat & OR Upcoming New Approach Replace Tree-Lines by Tree-Curves: Challenge: Solve Optimization problem Currently Open Problem Np complete??? Current Approach: Heuristics based approximate solution
123
123 UNC, Stat & OR Upcoming New Approach Replace Tree-Lines by Tree-Curves:
124
124 UNC, Stat & OR Upcoming New Approach Replace Tree-Lines by Tree-Curves: Notes: Back bushier on right (consistent) Right has much longer curve This was for Thickness Correspondence
125
125 UNC, Stat & OR Upcoming New Approach Projections on Tree-Curves (Thickness): Display: Show: Tree ⋂ Projection Show: Tree \ Projection Show: Projection \ Tree
126
126 UNC, Stat & OR Upcoming New Approach Projections on Tree-Curves (Thickness):
127
127 UNC, Stat & OR Upcoming New Approach Scores for Thickness Tree-Curves: Skewed Distributions Too many small scores Poor Repres’n?
128
128 UNC, Stat & OR Upcoming New Approach Scores for Descendants Tree-Curves: “Gaussian” Distributions Good spread of scores Better Repres’n?
129
129 UNC, Stat & OR Preliminary Tree-Curve Results Relate Tree Curve Scores to Age: Fit line to highlight dependence Test Slope Hypothesis Assess with p-value
130
130 UNC, Stat & OR Preliminary Tree-Curve Results Relate Tree Curve Scores to Age (Thickness): Back: No Sign’t Slope Don’t Find Relat’n
131
131 UNC, Stat & OR Preliminary Tree-Curve Results Relate Tree Curve Scores to Age (Descendants): Back: Sign’t Slope Now Find Relat’n Better Corr.?
132
132 UNC, Stat & OR Preliminary Tree-Curve Results Relate Tree Curve Scores to Age (Thickness): Left: No Sign’t Slope Don’t Find Relat’n
133
133 UNC, Stat & OR Preliminary Tree-Curve Results Relate Tree Curve Scores to Age (Descendants): Left: Sign’t Slope Now Find Relat’n Again: Better Corr.?
134
134 UNC, Stat & OR Preliminary Tree-Curve Results Relate Tree Curve Scores to Age (Thickness): Right: Sign’t Slope Now Find Relat’n?!?
135
135 UNC, Stat & OR Preliminary Tree-Curve Results Relate Tree Curve Scores to Age (Descendants): Right: No Sign’t Slope No Relat’n?!? Really have: Better Corr.?
136
136 UNC, Stat & OR Improved Correspondence Overall Impressions: Tree Curves better than Tree Lines Explain more variation Found more age structure Descendant Corr. better than Thickness Better Scores Distribution Found more age structure
137
137 UNC, Stat & OR Strongly Non-Euclidean Spaces Overall Impression: Interesting new OODA Area Much to be to done: Refined PCA Alternate tree lines Attributes (i.e. go beyond topology) Classification / Discrimination (SVM, DWD) Other data types (e.g. lung airways…)
138
138 UNC, Stat & OR Blood vessel tree data Big Picture: 3 Approaches 1.Purely Combinatorial 2.Euclidean Orthant 3.Harris Correspondence
139
139 UNC, Stat & OR Euclidean Orthant Approach People: Scott Provan Sean Skwerer Megan Owen Martin Styner Ipek Oguz
140
140 UNC, Stat & OR Euclidean Orthant Approach Setting: Connectivity & Length Background: Phylogenetic Trees Major Restriction: Need common leaves Big Payoff: Data space nearly Euclidean
141
141 UNC, Stat & OR Euclidean Orthant Approach Big Payoff: Data space nearly Euclidean
142
142 UNC, Stat & OR Euclidean Orthant Approach Big Payoff: Data space nearly Euclidean
143
143 UNC, Stat & OR Euclidean Orthant Approach Big Payoff: Data space nearly Euclidean
144
144 UNC, Stat & OR Euclidean Orthant Approach Major Restriction: Need common leaves Approach: Find common cortical landmarks corresponding across cases Treat as pseudo – leaves by projecting to points on tree (draw pic)
145
145 UNC, Stat & OR Blood vessel tree data Marron’s brain: From MRA Reconstruct trees in 3d Rotate to view
146
146 UNC, Stat & OR Vessel Locations
147
147 UNC, Stat & OR Vessel Locations
148
148 UNC, Stat & OR Vessel Locations
149
149 UNC, Stat & OR Vessel Locations
150
150 UNC, Stat & OR Vessel Locations
151
151 UNC, Stat & OR Vessel Locations
152
152 UNC, Stat & OR Common Color
153
153 UNC, Stat & OR Common Color
154
154 UNC, Stat & OR Common Color
155
155 UNC, Stat & OR Common Color
156
156 UNC, Stat & OR Common Color
157
157 UNC, Stat & OR Common Color
158
158 UNC, Stat & OR Cortical Surface & Landmarks
159
159 UNC, Stat & OR Cortical Surface & Landmarks
160
160 UNC, Stat & OR Cortical Surface & Landmarks
161
161 UNC, Stat & OR Cortical Surface & Landmarks
162
162 UNC, Stat & OR Cortical Surface & Landmarks
163
163 UNC, Stat & OR Cortical Surface & Landmarks
164
164 UNC, Stat & OR Landmarks and Vessels
165
165 UNC, Stat & OR Landmarks and Vessels
166
166 UNC, Stat & OR Landmarks and Vessels
167
167 UNC, Stat & OR Landmarks and Vessels
168
168 UNC, Stat & OR Landmarks and Vessels
169
169 UNC, Stat & OR Landmarks and Vessels
170
170 UNC, Stat & OR Attach Landmarks & Subtrees
171
171 UNC, Stat & OR Attach Landmarks & Subtrees
172
172 UNC, Stat & OR Attach Landmarks & Subtrees
173
173 UNC, Stat & OR Attach Landmarks & Subtrees
174
174 UNC, Stat & OR Attach Landmarks & Subtrees
175
175 UNC, Stat & OR Attach Landmarks & Subtrees
176
176 UNC, Stat & OR Highlight Oprhans
177
177 UNC, Stat & OR Highlight Oprhans
178
178 UNC, Stat & OR Highlight Oprhans
179
179 UNC, Stat & OR Highlight Oprhans
180
180 UNC, Stat & OR Highlight Oprhans
181
181 UNC, Stat & OR Highlight Oprhans
182
182 UNC, Stat & OR Trim Oprhans
183
183 UNC, Stat & OR Trim Oprhans
184
184 UNC, Stat & OR Trim Oprhans
185
185 UNC, Stat & OR Trim Oprhans
186
186 UNC, Stat & OR Trim Oprhans
187
187 UNC, Stat & OR Trim Oprhans
188
188 UNC, Stat & OR Final Tree (common leaves)
189
189 UNC, Stat & OR Final Tree (common leaves)
190
190 UNC, Stat & OR Final Tree (common leaves)
191
191 UNC, Stat & OR Final Tree (common leaves)
192
192 UNC, Stat & OR Final Tree (common leaves)
193
193 UNC, Stat & OR Final Tree (common leaves)
194
194 UNC, Stat & OR Blood vessel tree data Big Picture: 3 Approaches 1.Purely Combinatorial 2.Euclidean Orthant 3.Harris Correspondence
195
195 UNC, Stat & OR Harris Correspondence Approach People: Shankar Bhamidi Dan Shen
196
196 UNC, Stat & OR Harris Correspondence Approach Setting: Start with connectivity only Should be generalizable
197
197 UNC, Stat & OR Harris Correspondence Approach Idea: Represent trees as functions (draw some pics)
198
198 UNC, Stat & OR Harris Correspondence Approach Idea: Represent trees as functions Common device in probability theory Used for limiting distributions Gives access to Brownian Motion limits Use “Functional Data Analysis” Familiar, Euclidean space Many methods available
199
199 UNC, Stat & OR Harris Correspondence Approach Very new idea, no results yet.
Similar presentations
