Tutorials on the Shape modelling toolbox: Difference between revisions

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The models shown in these tutorials illustrate features of the AAMToolbox software. They are not designed to understand the shape and appearance modelling which is better done from the published literature [http://www.computer.org/portal/web/csdl/doi/10.1109/34.982900 for example].<br>
The models shown in these tutorials illustrate features of the AAMToolbox software. They are not designed to understand the shape and appearance modelling which is better done from the published literature [http://www.computer.org/portal/web/csdl/doi/10.1109/34.982900 for example].<br>
Viewing these pages. Some versions of ''Firefox'' and ''Explorer'' do not create satisfactory prints even though you can view the pages with no problems. ''Chrome'' does appear to produce good printouts.
Viewing these pages. Some versions of ''Firefox'' and ''Explorer'' do not create satisfactory prints even though you can view the pages with no problems. ''Chrome'' does appear to produce good printouts.
=Four ways to use ''AAMToolbox ''=
=Appearance models use OpenGL code to warp the image=
This means that the C code needs to be recompiled whenever Matlab/OS changes. All the required files are in the Directory BuildSFAM. [[Compiling AAMToolbox triwarp |Compiling AAMToolbox triwarp]]<br><br>
=<span style="color:Navy;">Fives ways to use ''AAMToolbox ''=
1) [[AAMToolbox Documentation#2 Creating shape models in 2D| '''Analysing shapes.''']] i.e. the arrangement of points around a shape<br><br>
1) [[AAMToolbox Documentation#2 Creating shape models in 2D| '''Analysing shapes.''']] i.e. the arrangement of points around a shape<br><br>
2) [[AAMToolbox Documentation#1 Creating shape models in 2D| '''Comparing shapes from samples of different groups''']] for example, comparing faces from different cartoon characters<br><br>
2) [[AAMToolbox Documentation#5 Viewing the data in shape space| '''Viewing the data in ''shape space''.''']] i.e. approximating the data with two principle components<br><br>
3) [[AAMToolbox Documentation#3 Analysing both shape and appearance in 2D|'''Analysing shape and appearance.''']] In addition to the points around a shape, analyse the appearance (grey scale or colour) within the shape.<br><br>  
3) [[AAMToolbox Documentation#1 Creating shape models in 2D| '''Comparing shapes from samples of different groups''']] for example, comparing faces from different cartoon characters<br><br>
4) [[AAMToolbox Documentation#4 Creating shape models in 3D|'''Analysing 3D shapes''']]  
4) [[AAMToolbox Documentation#3 Analysing both shape and appearance in 2D|'''Analysing shape and appearance.''']] In addition to the points around a shape, analyse the appearance (grey scale or colour) within the shape.<br><br>  
 
5) [[AAMToolbox Documentation#4 Creating shape models in 3D|'''Analysing 3D shapes''']]  
='''1''' Analysing 2D shapes using the Graphical User Interface=
<br><br>
 
'''How to use these tutorials.''' First [[AAMToolbox Download|download and install the AAMToolbox]]. A zip file containing the project (''PRJ_CartoonFaces'') is available [http://cmpdartsvr1.cmp.uea.ac.uk/downloads/software/PRJ_CartoonFaces.zip here]. Download and unzip into a directory. Then, from Matlab, change directory into the project and launch the AAMToolbox  
'''How to use the tutorial.''' First [[AAMToolbox Download|download and install the AAMToolbox]]. A zip file containing the project (''PRJ_CartoonFaces'') is available [http://cmpdartsvr1.cmp.uea.ac.uk/downloads/software/PRJ_CartoonFaces.zip here]. Download and unzip into a directory. Then, from Matlab, change directory into the project and launch the AAMToolbox  
  cd PRJ_CartoonFaces
  cd PRJ_CartoonFaces
  AAMToolbox  
  AAMToolbox  
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  Image:CB9.jpg
  Image:CB9.jpg
  </gallery>
  </gallery>
='''1''' <span style="color:Navy;">'''How''' to analyse 2D shapes using the Graphical User Interface</span>=
The process of analysing a set of images is:-
The process of analysing a set of images is:-
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#Create a new project. AAMToolbox project names are automatically prefaced with PRJ_. They have a particular directory structure and the images to be analysed need to be copied into the subdirectory called Cropped. It is best if they are all the same size.
#Create a '''new project'''. AAMToolbox project names are automatically prefaced with PRJ_. They have a particular directory structure and the images to be analysed need to be copied into the subdirectory called Cropped. It is best if they are all the same size.
#*[[AAMToolbox new project|Tutorial on making a new project.]]
#*[[AAMToolbox new project|Tutorial on making a new project.]]
#Create a point model template. Points are placed around the object of interest, i.e. around a face or leaf. The set of points constitute the '''point model'''.  Every image will be marked up in the same way.  
#'''Create a point model''' template. Points are placed around the object of interest, i.e. around a face or leaf. The set of points constitute the '''point model'''.  Every image will be marked up in the same way.  
#*[[AAMToolbox template|Tutorial on point model template.]]
#*[[AAMToolbox template|Tutorial on point model template.]]
#Move the points to the corresponding positions in each image in turn. The positions must'' '''correspond''' to the same material points'' in each image, i.e. the tip of the leaf, the corner of an eye, or halfway along a line between the two ends of the mouth.
#To '''digitise each image''', move the points to the corresponding positions in each image in turn. The positions must'' '''correspond''' to the same material points'' in each image, i.e. the tip of the leaf, the corner of an eye, or halfway along a line between the two ends of the mouth.
#*[[AAMToolbox point model editor|Tutorial on point model editor.]]
#*[[AAMToolbox point model editor|Tutorial on point model editor.]]
#Generate the shape model using principal component analysis (PCA)
#Generate the shape model using''' principal component analysis (PCA)'''
#*[[AAMToolbox statistical model generator|Tutorial on statistical model generator.]]
#*[[AAMToolbox statistical model generator|Tutorial on statistical model generator.]]
#View the result by varying each important component in turn. We call this ''walking'' the shape model. This movie shows a walk.
#'''View the result''' by varying each important component in turn. We call this ''walking'' the shape model. This movie shows a walk.
#*[[AAMToolbox viewing statistical model|Tutorial on viewing statistical model.]]
#*[[AAMToolbox viewing statistical model|Tutorial on viewing statistical model.]]
|width="300pt"|<wikiflv width="300" height="300" logo="false"  loop="true" background="white">CartoonPC1.flv|CartoonPC1.png</wikiflv>
#'''Best fit point model''' using only the principle components.
#*[[AAMToolbox simplify point model|Tutorial on fitting a model to a particular image.]]
|width="300pt"|<wikiflv width="300" height="300" logo="false"  loop="true" background="white">CartoonPC1.flv|CartoonPC1.png</wikiflv><br>
Mean shape (points) joined by lines. The movie shows deviations from the mean by varying the principle component.
|}
|}
='''2''' Viewing the data in ''Shape-Space''=
='''2''' <span style="color:Navy;">'''Viewing the results''' in ''Shape-Space''.''' What is Shape-Space?'''</span>=


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#PCA allows us to view the statistical model from a new angle: ''Shape Space''. This movie shows a trajectory through shape space.
#PCA allows us to view the data from a new angle: ''Shape Space'' rather than normal viewing space. This movie shows a trajectory through shape space that is projected back into normal viewing space.
#*[[AAMToolbox viewing one population in shape space|Tutorial on shape space.]]
#*[[AAMToolbox viewing one population in shape space|Tutorial on shape space.]]
|width="300pt"|<wikiflv width="300" height="300" logo="false"  loop="true" background="white">Movie-2012-02-15t10-48-49.flv|CartoonPC1.png</wikiflv>
|width="300pt"|<wikiflv width="300" height="300" logo="false"  loop="true" background="white">CartoonPC2.flv|PC2_cartoon_2.png</wikiflv><br>
Interpolating a walk from one point model shape to another in shape space.
|}
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='''3''' Comparing shapes from samples of different groups'=
 
----
=Seen these elsewhere?=
[[Image:PortraitsMEANSsmaller.jpg|800px]]
='''3''' <span style="color:Navy;">'''Comparing shapes''' in ''Shape-Space''.</span>=


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None of the above portraits exist. They were created by placing point models on samples of each painters work and computing the PCA of both the shape and the appearance. Each image is the mean shape coloured with the mean appearance. Dates: Giotto (~1300), Leonardo da Vinci (~1600), Valazquez (~1630), Rembrandt (~1650), Modigliani (~1900), Soutine (~1930).
#Compare shapes of different populations in shape space.
#*Groups of samples can be projected into a common shape space and compared. In this case portraits.
#*By focussing on the main contributions to shape it might be possible to relate positions in shape space to, for example, genotype in leaves ([http://www.pnas.org/content/102/29/10221.short Langlade ''et al'' 2005.],[http://www.tandfonline.com/doi/abs/10.2976/1.2836738 Bensmihen ''et al.'' 2010]) and petals ([http://www.sciencemag.org/content/313/5789/963.short Whibley ''et al'' 2006],[http://www.mssaleshops.info/content/21/10/2999.short Feng ''et al''. 2010])
#*In the portraits example (right) imagine a diagonal line roughly from top-left to bottom right. It goes from Rembrandt to El Greco. We might note that Modigliani and Soutine are closer to the stylised images of El Greco than pictures from the middle period (1600<=middle<=1930) when the artists appear to have aimed for realism.
#[[Shape and GFtbox modelling| Tutorial on shape and GFtbox modelling]]
|width="300pt"|[[Image:AAMToolboxPortraitsShapeSpace.jpg|400px]]Portraits by different painters projected into a shape space created by PCA of all the results. Conclusions?


#View the result by varying each important component in turn. We call this ''walking'' the shape model. This movie shows a walk.
#*[[AAMToolbox viewing statistical model|Tutorial on viewing statistical model.]]
|width="300pt"|<wikiflv width="300" height="300" logo="false"  loop="true" background="white">ShapeVectorWalkShowShape-21-Jun-2011-14-28-24 VD.flv|ShapeVectorWalkShowShape-21-Jun-2011-14-28-24 VD_First.png</wikiflv>
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===1 B===

Latest revision as of 18:30, 2 July 2014

Back to AAMToolbox Documentation

The models shown in these tutorials illustrate features of the AAMToolbox software. They are not designed to understand the shape and appearance modelling which is better done from the published literature for example.
Viewing these pages. Some versions of Firefox and Explorer do not create satisfactory prints even though you can view the pages with no problems. Chrome does appear to produce good printouts.

Appearance models use OpenGL code to warp the image

This means that the C code needs to be recompiled whenever Matlab/OS changes. All the required files are in the Directory BuildSFAM. Compiling AAMToolbox triwarp

Fives ways to use AAMToolbox

1) Analysing shapes. i.e. the arrangement of points around a shape

2) Viewing the data in shape space. i.e. approximating the data with two principle components

3) Comparing shapes from samples of different groups for example, comparing faces from different cartoon characters

4) Analysing shape and appearance. In addition to the points around a shape, analyse the appearance (grey scale or colour) within the shape.

5) Analysing 3D shapes

How to use these tutorials. First download and install the AAMToolbox. A zip file containing the project (PRJ_CartoonFaces) is available here. Download and unzip into a directory. Then, from Matlab, change directory into the project and launch the AAMToolbox

cd PRJ_CartoonFaces
AAMToolbox 

This project contains as set of faces that have been analysed using 2D shape models

1 How to analyse 2D shapes using the Graphical User Interface

The process of analysing a set of images is:-

  1. Create a new project. AAMToolbox project names are automatically prefaced with PRJ_. They have a particular directory structure and the images to be analysed need to be copied into the subdirectory called Cropped. It is best if they are all the same size.
  2. Create a point model template. Points are placed around the object of interest, i.e. around a face or leaf. The set of points constitute the point model. Every image will be marked up in the same way.
  3. To digitise each image, move the points to the corresponding positions in each image in turn. The positions must correspond to the same material points in each image, i.e. the tip of the leaf, the corner of an eye, or halfway along a line between the two ends of the mouth.
  4. Generate the shape model using principal component analysis (PCA)
  5. View the result by varying each important component in turn. We call this walking the shape model. This movie shows a walk.
  6. Best fit point model using only the principle components.
<wikiflv width="300" height="300" logo="false" loop="true" background="white">CartoonPC1.flv|CartoonPC1.png</wikiflv>

Mean shape (points) joined by lines. The movie shows deviations from the mean by varying the principle component.

2 Viewing the results in Shape-Space. What is Shape-Space?

  1. PCA allows us to view the data from a new angle: Shape Space rather than normal viewing space. This movie shows a trajectory through shape space that is projected back into normal viewing space.
<wikiflv width="300" height="300" logo="false" loop="true" background="white">CartoonPC2.flv|PC2_cartoon_2.png</wikiflv>

Interpolating a walk from one point model shape to another in shape space.


Seen these elsewhere?

PortraitsMEANSsmaller.jpg

3 Comparing shapes in Shape-Space.

None of the above portraits exist. They were created by placing point models on samples of each painters work and computing the PCA of both the shape and the appearance. Each image is the mean shape coloured with the mean appearance. Dates: Giotto (~1300), Leonardo da Vinci (~1600), Valazquez (~1630), Rembrandt (~1650), Modigliani (~1900), Soutine (~1930).

  1. Compare shapes of different populations in shape space.
    • Groups of samples can be projected into a common shape space and compared. In this case portraits.
    • By focussing on the main contributions to shape it might be possible to relate positions in shape space to, for example, genotype in leaves (Langlade et al 2005.,Bensmihen et al. 2010) and petals (Whibley et al 2006,Feng et al. 2010)
    • In the portraits example (right) imagine a diagonal line roughly from top-left to bottom right. It goes from Rembrandt to El Greco. We might note that Modigliani and Soutine are closer to the stylised images of El Greco than pictures from the middle period (1600<=middle<=1930) when the artists appear to have aimed for realism.
  2. Tutorial on shape and GFtbox modelling
AAMToolboxPortraitsShapeSpace.jpgPortraits by different painters projected into a shape space created by PCA of all the results. Conclusions?