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Part 2: part-based models
by Rob Fergus (MIT)
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Problem with bag-of-words
Motivation slide. Clearly location has to help, but bag-of-words doesn’t have it… All have equal probability for bag-of-words methods Location information is important
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Overview of section Representation Recognition
Computational complexity Location Appearance Occlusion, Background clutter Recognition Demos
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Representation
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Model: Parts and Structure
Globally different, but have portions in common
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Representation Object as set of parts Model:
Generative representation Model: Relative locations between parts Appearance of part Issues: How to model location How to represent appearance Sparse or dense (pixels or regions) How to handle occlusion/clutter Figure from [Fischler & Elschlager 73]
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History of Parts and Structure approaches
Fischler & Elschlager 1973 Yuille ‘91 Brunelli & Poggio ‘93 Lades, v.d. Malsburg et al. ‘93 Cootes, Lanitis, Taylor et al. ‘95 Amit & Geman ‘95, ‘99 Perona et al. ‘95, ‘96, ’98, ’00, ’03, ‘04, ‘05 Felzenszwalb & Huttenlocher ’00, ’04 Crandall & Huttenlocher ’05, ’06 Leibe & Schiele ’03, ’04 Many papers since 2000
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Sparse representation
+ Computationally tractable (105 pixels parts) + Generative representation of class + Avoid modeling global variability + Success in specific object recognition - Throw away most image information - Parts need to be distinctive to separate from other classes
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Region operators Local maxima of interest operator function
Can give scale/orientation invariance Figures from [Kadir, Zisserman and Brady 04]
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The correspondence problem
Model with P parts Image with N possible assignments for each part Consider mapping to be 1-1 Key problem with approach & motivates design choices. Assume for the moment that we have a set of regions. NP combinations!!!
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The correspondence problem
1 – 1 mapping Each part assigned to unique feature As opposed to: 1 – Many Bag of words approaches Sudderth, Torralba, Freeman ’05 Loeff, Sorokin, Arora and Forsyth ‘05 Many – 1 - Quattoni, Collins and Darrell, 04
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Location
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Connectivity of parts Complexity is given by size of maximal clique in graph Consider a 3 part model Each part has set of N possible locations in image Location of parts 2 & 3 is independent, given location of L Each part has an appearance term, independent between parts. Shape Model Factor graph Variables L 2 3 L 2 3 Factors S(L) S(L,2) S(L,3) A(L) A(2) A(3) Shape Appearance
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Different connectivity structures
Felzenszwalb & Huttenlocher ‘00 Fergus et al. ’03 Fei-Fei et al. ‘03 Crandall et al. ‘05 Fergus et al. ’05 Crandall et al. ‘05 O(N2) O(N6) O(N2) O(N3) Csurka ’04 Vasconcelos ‘00 Bouchard & Triggs ‘05 Carneiro & Lowe ‘06 from Sparse Flexible Models of Local Features Gustavo Carneiro and David Lowe, ECCV 2006
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How much does shape help?
Crandall, Felzenszwalb, Huttenlocher CVPR’05 Shape variance increases with increasing model complexity Do get some benefit from shape
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Hierarchical representations
Pixels Pixel groupings Parts Object Multi-scale approach increases number of low-level features Amit and Geman ‘98 Bouchard & Triggs ‘05 Images from [Amit98,Bouchard05]
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Some class-specific graphs
Articulated motion People Animals Special parameterisations Limb angles Images from [Kumar, Torr and Zisserman 05, Felzenszwalb & Huttenlocher 05]
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Dense layout of parts Layout CRF: Winn & Shotton, CVPR ‘06
Part labels (color-coded) Each pixel is labelled – regions of pixels have the same part label. 18
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How to model location? Explicit: Probability density functions
Implicit: Voting scheme Invariance Translation Scaling Similarity/affine Viewpoint Affine transformation Similarity transformation Translation and Scaling Translation
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Explicit shape model Cartesian Polar E.g. Gaussian distribution
Parameters of model, and Independence corresponds to zeros in Burl et al. ’96, Weber et al. ‘00, Fergus et al. ’03 Polar Convenient for invariance to rotation Mikolajczyk et al., CVPR ‘06
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Spatial occurrence distributions Matched Codebook Entries
Implicit shape model Use Hough space voting to find object Leibe and Schiele ’03,’05 Spatial occurrence distributions x y s Learning Learn appearance codebook Cluster over interest points on training images Learn spatial distributions Match codebook to training images Record matching positions on object Centroid is given Recognition Matched Codebook Entries Probabilistic Voting Interest Points
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Deformable Template Matching
Berg, Berg and Malik CVPR 2005 Template Query Formulate problem as Integer Quadratic Programming O(NP) in general Use approximations that allow P=50 and N=2550 in <2 secs % The idea of deformable templates is not new. In % the early 1970's at least three groups were % working on similar ideas: % Grenander in statistical pattern theory % von der Malsburg in neural networks % and Fischler and Eschlager in computer vision On the left we have the model template of a helicopter. We characterize the template by a set of feature points sampled from edges in the image. These are shown as the approximately 40 colored dots in the left image. On the right we show a query image. Here feature points are extracted along edges in the entire image. Many of these will be on background or clutter, but some are on the object of interest. Our problem is to find a correspondence between the model points at left and the correct subset of feature points on the right.
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Other invariance methods
Search over transformations Large space (# pixels x # scales ….) Closed form solution for translation and scale (Helmer and Lowe ’04) Features give information Characteristic scale Characteristic orientation (noisy) invariance of the characteristic scale Figures from Mikolajczyk & Schmid
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Multiple views Mixture of 2-D models Frontal Profile
Weber, Welling and Perona CVPR ‘00 20 40 60 80 100 50 55 65 70 75 85 90 95 Orientation Tuning angle in degrees % Correct Component 1 Component 2 Frontal Profile
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Multiple view points Thomas, Ferrari, Leibe, Tuytelaars, Schiele, and L. Van Gool. Towards Multi-View Object Class Detection, CVPR 06 Hoiem, Rother, Winn, 3D LayoutCRF for Multi-View Object Class Recognition and Segmentation, CVPR ‘07
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Appearance
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Representation of appearance
Needs to handle intra-class variation Task is no longer matching of descriptors Implicit variation (VQ to get discrete appearance) Explicit model of appearance (e.g. Gaussians in SIFT space) Dependency structure Often assume each part’s appearance is independent Common to assume independence with location
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Representation of appearance
Invariance needs to match that of shape model Insensitive to small shifts in translation/scale Compensate for jitter of features e.g. SIFT Illumination invariance Normalize out
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Appearance representation
SIFT Decision trees [Lepetit and Fua CVPR 2005] PCA Figure from Winn & Shotton, CVPR ‘06
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Occlusion Explicit Implicit
Additional match of each part to missing state Implicit Truncated minimum probability of appearance µpart Appearance space Log probability
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Background clutter Explicit model Use a sub-window
Generative model for clutter as well as foreground object Use a sub-window At correct position, no clutter is present
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Recognition
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What task? Classification Localization / Detection
Object present/absent in image Background may be correlated with object Localization / Detection Localize object within the frame Bounding box or pixel-level segmentation
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Efficient search methods
Interpretation tree (Grimson ’87) Condition on assigned parts to give search regions for remaining ones Branch & bound, A*
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Distance transforms Felzenszwalb and Huttenlocher ’00 & ’05
2 Model Felzenszwalb and Huttenlocher ’00 & ’05 Distance transforms O(N2P) O(NP) for tree structured models How it works Assume location model is Gaussian (i.e. e-d2 ) Consider a two part model with µ=0, σ=1 on a 1-D image xi Image pixel Appearance log probability at xi for part 2 = A2(xi) Log probability f(d) = -d2
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Distance transforms 2 For each position of landmark part, find best position for part 2 Finding most probable xi is equivalent finding maximum over set of offset parabolas Upper envelope computed in O(N) rather than obvious O(N2) via distance transform (see Felzenszwalb and Huttenlocher ’05). Add AL(x) to upper envelope (offset by µ) to get overall probability map xg xh xi xj xk xl Image pixel A2(xi) A2(xl) A2(xj) A2(xg) A2(xh) A2(xk) Log probability
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Parts and Structure demo
Gaussian location model – star configuration Translation invariant only Use 1st part as landmark Appearance model is template matching Manual training User identifies correspondence on training images Recognition Run template for each part over image Get local maxima set of possible locations for each part Impose shape model - O(N2P) cost Score of each match is combination of shape model and template responses.
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Demo images Sub-set of Caltech face dataset Caltech background images
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Demo Web Page
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Demo (2)
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Demo (3)
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Demo (4)
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Demo: efficient methods
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Stochastic Grammar of Images S.C. Zhu et al. and D. Mumford
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Context and Hierarchy in a Probabilistic Image Model Jin & Geman (2006)
animal head instantiated by bear head e.g. animals, trees, rocks e.g. contours, intermediate objects e.g. linelets, curvelets, T-junctions e.g. discontinuities, gradient animal head instantiated by tiger head
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Parts and Structure models Summary
Correspondence problem Efficient methods for large # parts and # positions in image Challenge to get representation with desired invariance Future directions: Multiple views Approaches to learning Multiple category training
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References 2. Parts and Structure
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[FeiFei03] L. Fei-Fei, R. Fergus, and P. Perona
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[Grimson87] W. E. L. Grimson and T. Lozano-Perez
[Grimson87] W. E. L. Grimson and T. Lozano-Perez. Localizing overlapping parts by searching the interpretation tree. IEEE Transactions on Pattern Analysis and Machine Intelligence, 9(4): , 1987. [Harris98] C. J. Harris and M. Stephens. A combined corner and edge detector. In Proceedings of the 4th Alvey Vision Conference, Manchester, pages , 1988. [Hart68] P.E. Hart, N.J. Nilsson, and B. Raphael. A formal basis for the determination of minimum cost paths. IEEE Transactions on SSC, 4: , 1968. [Helmer04] S. Helmer and D. Lowe. Object recognition with many local features. In Workshop on Generative Model Based Vision 2004 (GMBV), Washington, D.C., July 2004. [Hofmann99] T. Hofmann. Probabilistic latent semantic indexing. In SIGIR '99: Proceedings of the 22nd Annual International ACM SIGIR Conference on Research and Development in Information Retrieval, August 15-19, 1999, Berkeley, CA, USA, pages ACM, 1999. [Holub05] A. Holub and P. Perona. A discriminative framework for modeling object classes. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, San Diego, volume 1, pages , 2005. [Kadir01] T. Kadir and M. Brady. Scale, saliency and image description. International Journal of Computer Vision, 45(2):83-105, 2001. [Kadir_Code] T. Kadir and M. Brady. Scale Scaliency Operator. ~timork/salscale.html, 2003. [Kumar05] M. P. Kumar, P. H. S. Torr, and A. Zisserman. Obj cut. In Proceedings of IEEE Conference on Computer Vision and Pattern Recognition, San Diego, pages 18-25, 2005. [Leibe04] B. Leibe, A. Leonardis, and B. Schiele. Combined object categorization and segmentation with an implicit shape model. In Workshop on Statistical Learning in Computer Vision, ECCV, 2004. [Leung98] T. Leung and J. Malik. Contour continuity and region based image segmentation. In Proceedings of the 5th European Conference on Computer Vision, Freiburg, Germany, LNCS 1406, pages Springer-Verlag, 1998. [Leung95] T.K. Leung, M.C. Burl, and P. Perona. Finding faces in cluttered scenes using random labeled graph matching. Proceedings of the 5th International Conference on Computer Vision, Boston, pages , June 1995.
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[Leung98] T. K. Leung, M. C. Burl, and P. Perona
[Leung98] T.K. Leung, M.C. Burl, and P. Perona. Probabilistic ane invariants for recognition. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pages , 1998. [Lindeberg98] T. Lindeberg. Feature detection with automatic scale selection. International Journal of Computer Vision, 30(2):77-116, 1998. [Lowe99] D. Lowe. Object recognition from local scale-invariant features. In Proceedings of the 7th International Conference on Computer Vision, Kerkyra, Greece, pages , September 1999. [Lowe01] D. Lowe. Local feature view clustering for 3D object recognition. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, Kauai, Hawaii, pages Springer, December 2001. [Lowe04] D. Lowe. Distinctive image features from scale-invariant keypoints. International Journal of Computer Vision, 60(2):91-110, 2004. [Mardia89] K.V. Mardia and I.L. Dryden. \Shape Distributions for Landmark Data". Advances in Applied Probability, 21: , 1989. [Sivic05] J. Sivic, B. Russell, A. Efros, A. Zisserman, and W. Freeman. Discovering object categories in image collections. Technical Report A. I. Memo , Massachusetts Institute of Technology, 2005. [Sivic03] J. Sivic and A. Zisserman. Video Google: A text retrieval approach to object matching in videos. In Proceedings of the International Conference on Computer Vision, pages , October 2003. [Sudderth05] E. Sudderth, A. Torralba, W. Freeman, and A. Willsky. Learning hierarchical models of scenes, objects, and parts. In Proceedings of the IEEE International Conference on Computer Vision, Beijing, page To appear, 2005. [Torralba04] A. Torralba, K. P. Murphy, and W. T. Freeman. Sharing features: ecient boosting procedures for multiclass object detection. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, Washington, DC, pages , 2004.
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[Viola01] P. Viola and M. Jones
[Viola01] P. Viola and M. Jones. Rapid object detection using a boosted cascade of simple features. In Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition, pages 511{518, 2001. [Weber00] M.Weber. Unsupervised Learning of Models for Object Recognition. PhD thesis, California Institute of Technology, Pasadena, CA, 2000. [Weber00a] M. Weber, W. Einhauser, M. Welling, and P. Perona. Viewpoint-invariant learning and detection of human heads. In Proc. 4th IEEE Int. Conf. Autom. Face and Gesture Recog., FG2000, pages 20{27, March 2000. [Weber00b] M. Weber, M. Welling, and P. Perona. Towards automatic discovery of object categories. pages 2101{2108, June 2000. [Weber00c] M. Weber, M. Welling, and P. Perona. Unsupervised learning of models for recognition. In Proc. 6th Europ. Conf. Comp. Vis., ECCV2000, volume 1, pages 18{32, June 2000. [Welling05] M. Welling. An expectation maximization algorithm for inferring oset-normal shape distributions. In Tenth International Workshop on Articial Intelligence and Statistics, 2005. [Winn05] J. Winn and N. Joijic. Locus: Learning object classes with unsupervised segmentation. In Proceedings of the IEEE International Conference on Computer Vision, Beijing, page To appear, 2005
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Quest for A Stochastic Grammar of Images Song-Chun Zhu and David Mumford
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Example scheme Model shape using Gaussian distribution on location between parts Model appearance as pixel templates Represent image as collection of regions Extracted by template matching: normalized-cross correlation Manually trained model Click on training images
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Connectivity of parts To find best match in image, we want most probable state of L, Run max-product message passing L 2 3 md ma mb mc S(L) S(L,2) S(L,3) A(L) A(2) A(3) Take O(N2) to compute: For each of the N values of L, need to find max over N states
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Different graph structures
6 1 3 5 2 3 2 3 1 2 1 4 5 4 6 6 4 5 Fully connected Star structure Tree structure O(N6) O(N2) O(N2) Sparser graphs cannot capture all interactions between parts
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Euclidean & Affine Shape
Translation, rotation and scaling Euclidean Shape Removal of camera foreshortenings Affine Shape Assume Gaussian density in figure space What is the probability density for the shape variables in each of the different spaces? Feature space Translation Invariant shape Euclidean shape Affine shape Figures from [Leung98]
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Translation-invariant shape
Figure space density: Translation-invariant form e.g. P=3, move 1st part to origin Shape space density is still Gaussian
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Affine Shape Density Affine Shape density (Dryden-Mardia):
Euclidean Shape density is of similar form Can learnt parameters of DM density with EM! [Leung98],[Welling05]
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Shape Shape is “what remains after differences due to translation, rotation, and scale have been factored out”. [Kendall84] Statistical theory of shape [Kendall, Bookstein, Mardia & Dryden] Y V X U Figure Space Shape Space Figures from [Leung98]
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Learning
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Learning situations Varying levels of supervision
Unsupervised Image labels Object centroid/bounding box Segmented object Manual correspondence (typically sub-optimal) Generative models naturally incorporate labelling information (or lack of it) Discriminative schemes require labels for all data points Contains a motorbike
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Learning using EM Task: Estimation of model parameters
Chicken and Egg type problem, since we initially know neither: Model parameters - Assignment of regions to parts Let the assignments be a hidden variable and use EM algorithm to learn them and the model parameters
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Learning procedure Find regions & their location & appearance
Initialize model parameters Use EM and iterate to convergence: E-step: Compute assignments for which regions belong to which part M-step: Update model parameters Trying to maximize likelihood – consistency in shape & appearance
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Example scheme, using EM for maximum likelihood learning
1. Current estimate of 2. Assign probabilities to constellations Large P ... pdf Image 1 Image 2 Image i Small P 3. Use probabilities as weights to re-estimate parameters. Example: Large P x + Small P x + … = new estimate of
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Priors Implicit Explicit model () space 1 2 n
Structure of dependencies in model Parameterisation of model Feature detectors Explicit p() MAP / Bayesian learning Fei-Fei ‘03 model () space 1 2 n p(n ) p(2 ) p(1 )
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Learning Shape & Appearance simultaneously
Fergus et al. ‘03
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Learn appearance then shape
Weber et al. ‘00 Model 1 Choice 1 Parameter Estimation Model 2 Choice 2 Parameter Estimation Preselected Parts (100) Predict / measure model performance (validation set or directly from model)
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Discriminative training
Sparse so parts need to be distinctive of class Boosted parts and structure models Amores et al. CVPR 2005 Bar Hillel et al. CVPR 2005 Discriminative features Weber et al. 2000 Ullman et al. Train discriminatively on parameters of generative model Holub, Welling, Perona ICCV 2005
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Number of training images
More supervision, fewer images needed Few unknown parameters Less supervision, more images. Lots of unknown parameters Over-fitting problems
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Number of training examples
6 part Motorbike model Priors
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