Mercurial > cortex
diff org/literature-review.org @ 377:80cd096682b2
reviewing ullman's stuff.
author | Robert McIntyre <rlm@mit.edu> |
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date | Thu, 11 Apr 2013 06:19:59 +0000 |
parents | 057d47fc4789 |
children | 8e62bf52be59 |
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1.1 --- a/org/literature-review.org Thu Apr 11 05:40:23 2013 +0000 1.2 +++ b/org/literature-review.org Thu Apr 11 06:19:59 2013 +0000 1.3 @@ -208,6 +208,8 @@ 1.4 cross-validation = train the model on two different sets to prevent 1.5 overfitting. 1.6 1.7 +nifty, relevant, realistic ideas 1.8 +He doesn't confine himself to unplasaubile assumptions 1.9 1.10 1.11 1.12 @@ -239,15 +241,20 @@ 1.13 better with few training points, and the more complex ones do 1.14 better with many training points. 1.15 1.16 + The final model had intermediate complexity between published 1.17 + extremes. 1.18 + 1.19 The more complex models must be able to be initialized efficiently 1.20 from the less complex models which they replace! 1.21 1.22 1.23 ** Non Parametric Models 1.24 1.25 -*** Visual features of intermediate complexity and their use in classification 1.26 +*** 2002 Visual features of intermediate complexity and their use in classification 1.27 1.28 -*** The chains model for detecting parts by their context 1.29 + 1.30 + 1.31 +*** 2010 The chains model for detecting parts by their context 1.32 1.33 Like the constelation method for rigid objects, but extended to 1.34 non-rigid objects as well. 1.35 @@ -257,4 +264,60 @@ 1.36 ambiguous in an image, but if you are expecting them at the end of 1.37 an arm, then they become easier to find. 1.38 1.39 - 1.40 \ No newline at end of file 1.41 + They make chains by using spatial proximity of features. That way, 1.42 + a hand can be idntified by chaining back from the head. If there 1.43 + is a good chain to the head, then it is more likely that there is 1.44 + a hand than if there isn't. Since there is some give in the 1.45 + proximity detection, the system can accomodate new poses that it 1.46 + has never seen before. 1.47 + 1.48 + Does not use any motion information. 1.49 + 1.50 +*** 2005 A Hierarchical Non-Parametric Method for Capturing Non-Rigid Deformations 1.51 + 1.52 + (relative dynamic programming [RDP]) 1.53 + 1.54 + Goal is to match images, as in SIFT, but this time the images can 1.55 + be subject to non rigid transformations. They do this by finding 1.56 + small patches that look the same, then building up bigger 1.57 + patches. They get a tree of patches that describes each image, and 1.58 + find the edit distance between each tree. Editing operations 1.59 + involve a coherent shift of features, so they can accomodate local 1.60 + shifts of patches in any direction. They get some cool results 1.61 + over just straight correlation. Basically, they made an image 1.62 + comparor that is resistant to multiple independent deformations. 1.63 + 1.64 + !important small regions are treated the same as nonimportant 1.65 + small regions 1.66 + 1.67 + !no conception of shape 1.68 + 1.69 + quote: 1.70 + The dynamic programming procedure looks for an optimal 1.71 + transformation that aligns the patches of both images. This 1.72 + transformation is not a global transformation, but a composition 1.73 + of many local transformations of sub-patches at various sizes, 1.74 + performed one on top of the other. 1.75 + 1.76 +*** 2006 Satellite Features for the Classification of Visually Similar Classes 1.77 + 1.78 + Finds features that can distinguish subclasses of a class, by 1.79 + first finding a rigid set of anghor features that are common to 1.80 + both subclasses, then finding distinguishing features relative to 1.81 + those subfeatures. They keep things rigid because the satellite 1.82 + features don't have much information in and of themselves, and are 1.83 + only informative relative to other features. 1.84 + 1.85 +*** 2005 Learning a novel class from a single example by cross-generalization. 1.86 + 1.87 + Let's you use a vast visual experience to generate a classifier 1.88 + for a novel class by generating synthetic examples by replaceing 1.89 + features from the single example with features from similiar 1.90 + classes. 1.91 + 1.92 + quote: feature F is likely to be useful for class C if a similar 1.93 + feature F proved effective for a similar class C in the past. 1.94 + 1.95 + Allows you to trasfer the "gestalt" of a similiar class to a new 1.96 + class, by adapting all the features of the learned class that have 1.97 + correspondance to the new class. 1.98 \ No newline at end of file