Hypercomplex Wavelets

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[[Image:Dhwt circle.png|thumb|right|400px|High- and low-frequency decomposition using the hypercomplex wavelet transform]]  
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[[Image:Steerablefilters.jpg|thumb|320px|right|Conference article [http://digitalcommons.shu.ac.uk/mmvl_papers/1/ Steerable filters generated with the hypercomplex dual-tree wavelet transform]]]
 
=Introduction=
 
=Introduction=
 
Complex wavelets are superior to real-valued wavelets because they are nearly shift-invariant. [[Complex Wavelet Filters|Complex wavelets]] yield amplitude-phase
 
Complex wavelets are superior to real-valued wavelets because they are nearly shift-invariant. [[Complex Wavelet Filters|Complex wavelets]] yield amplitude-phase
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signal locally and thus can be applied to signals with a non-stationary statistic (such as images of a natural scene). In the same
 
signal locally and thus can be applied to signals with a non-stationary statistic (such as images of a natural scene). In the same
 
way as a one-dimensional signal requires complex numbers to represent the local structure of the signal, two-dimensional signals
 
way as a one-dimensional signal requires complex numbers to represent the local structure of the signal, two-dimensional signals
require hypercomplex numbers. [http://www-sigproc.eng.cam.ac.uk/~ngk/ Kingsbury] has developed the '''Dual-Tree Hypercomplex Wavelet Transform''' (DHWT) which allows to recursively decompose a two-dimensional image.
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require hypercomplex numbers. [http://www-sigproc.eng.cam.ac.uk/~ngk/ Kingsbury] has developed the '''Dual-Tree Complex Wavelet Transform''' which allows to recursively compute complex wavelet transforms. Analogous to one-dimensional analysis requiring complex values, two-dimensional analysis requires 4-valued complex numbers (hypercomplex values). Bülow, Kingsbury, and others already have successfully used hypercomplex numbers for analysing two-dimensional signals.
  
 
=Implementation=
 
=Implementation=
[[HornetsEye]] now contains an implementation of the Dual-Tree Hypercomplex Wavelet Transform (DHWT). The implementation makes use of
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[[Image:Dhwt circle.png|thumb|right|400px|High- and low-frequency decomposition using the dual-tree complex wavelet transform. The approximate shift-invariance leads to reduced aliasing]]
Selesnick's [[Complex Wavelet Filters|Hilbert transform pairs of wavelet bases]]. The wavelet transform makes use of [[HornetsEye]]'s [http://www.wedesoft.demon.co.uk/hornetseye-api/files/MultiArray-rb.html MultiArray] class. Have a look at the
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[[HornetsEye]] now contains an implementation of the Dual-Tree Complex Wavelet Transform. The implementation makes use of [[Complex Wavelet Filters|Hilbert transform pairs of wavelet bases]]. The wavelet transform was implemented with [[HornetsEye]]'s **MultiArray** class.
[http://www.wedesoft.demon.co.uk/hornetseye-api/files/hypercomplex-txt.html hypercomplex wavelet example] for more information.
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=Wavelet Editor=
 
=Wavelet Editor=
[[Image:Waveletedit.png|thumb|240px|right|Wavelet editor]]
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[[Image:Waveletedit2.png|thumb|320px|right|Wavelet editor]]
 
An editor for visualising linear combinations of wavelets was implemented.
 
An editor for visualising linear combinations of wavelets was implemented.
The code requires [http://rubyforge.org/projects/korundum/ qt4-qtruby], and [[HornetsEye]]. Here is the source code:
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The code requires [http://rubyforge.org/projects/korundum/ qt4-qtruby], and [[HornetsEye]]. The source code is part of the [[HornetsEye]] source package. You may need to compile the user interface design file using ''rbuic4'' like this:
* Ruby program: [http://vision.eng.shu.ac.uk/jan/waveletEdit.rb waveletEdit.rb]
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* Qt4 design: [http://vision.eng.shu.ac.uk/jan/waveletEdit.ui waveletEdit.ui]
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You need to compile the design file using ''rbuic4'' like this:
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<pre>
 
<pre>
 
rbuic4 waveletEdit.ui > ui_waveletEdit.rb
 
rbuic4 waveletEdit.ui > ui_waveletEdit.rb
 
</pre>
 
</pre>
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You can view the source files in their current state at [http://bazaar.launchpad.net/%7Ewedesoft/hornetseye/trunk/files http://bazaar.launchpad.net/~wedesoft/hornetseye/trunk/files] in the subdirectory ''samples/hypercomplex''.
  
 
=See Also=
 
=See Also=
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=External Links=
 
=External Links=
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<html><div class="floatright"><span><a href="/mmvlwiki/index.php/Image:Wavelet_Transforms.gif" class="image" title=""><img src="/mmvlwiki/images/1/1b/Wavelet_Transforms.gif" alt="" width="120" longdesc="/mmvlwiki/index.php/Image:Wavelet_Transforms.gif" /></a></span></div></html>
 
* [http://taco.poly.edu/selesi/ Ivan Selesnick's homepage]
 
* [http://taco.poly.edu/selesi/ Ivan Selesnick's homepage]
 
* [http://www-sigproc.eng.cam.ac.uk/~ngk/ Nick Kingsbury's homepage]
 
* [http://www-sigproc.eng.cam.ac.uk/~ngk/ Nick Kingsbury's homepage]
* [http://home.comcast.net/~cmdaven/hyprcplx.htm Clyde Davenport's page on commutative hypercomplex mathematics]
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** N G Kingsbury: [http://www-sigproc.eng.cam.ac.uk/~ngk/publications/ngk_ACHApap.pdf Complex wavelets for shift invariant analysis and filtering of signals], Journal of Applied and Computational Harmonic Analysis, vol 10, no 3, May 2001
* [http://digitalcommons.shu.ac.uk/mmvl_papers/1/ J. Wedekind, B. Amavasai, K. Dutton: Steerable Filters Generated With The Hypercomplex Dual-Tree Wavelet Transform]
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** J Fauqueur, N Kingsbury and R Anderson: [http://www-sigproc.eng.cam.ac.uk/~ngk/publications/fauqueur_icip06.pdf Multiscale keypoint detection using the dual-tree complex wavelet transform], Proc. IEEE Conference on Image Processing, Atlanta, GA, 8-11 Oct 2006
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* Thomas Bülow: [http://www.ks.informatik.uni-kiel.de/~vision/doc/Dissertationen/Thomas_Buelow/diss.ps.gz Hypercomplex Spectral Signal Representations for Image Processing and Analysis], PhD thesis, 1999
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* J. Wedekind, B. Amavasai, K. Dutton: [http://shura.shu.ac.uk/953/ Steerable Filters Generated With The Hypercomplex Dual-Tree Wavelet Transform], ICSPC07 proceedings (also see [http://vision.eng.shu.ac.uk/jan/icspc07-foils.pdf foils (PDF)]) (I think there's a bug in the paper. I need to use <math>H_1(z)=(-z)^{-M}\,H_0(z^{-1})</math> (see Selesnicks paper) where <math>M</math> is odd. Maybe this explains the trouble I have with choosing the sampling offsets in some cases)
 
* [http://www.wedesoft.demon.co.uk/hornetseye-api/files/hypercomplex-txt.html Hypercomplex wavelet example]
 
* [http://www.wedesoft.demon.co.uk/hornetseye-api/files/hypercomplex-txt.html Hypercomplex wavelet example]
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* [http://www.walterpfeifer.ch/liealgebra/ The Lie Algebras su(N), an Introduction] by Walter Pfeifer
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* [http://arxiv.org/abs/0907.5356v1 Clifford algebra, geometric algebra, and applications], lecture notes by Douglas Lundholm, Lars Svensson
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* Related work
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** [http://home.comcast.net/~cmdaven/hyprcplx.htm Clyde Davenport's page on commutative hypercomplex mathematics]
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** K. Krajsek, R. Mester: [http://www.vsi.cs.uni-frankfurt.de/download/KrajsekVisapp06.pdf A Unified theory For Steerable And Quadrature Filters], International Conferences VISAPP and GRAPP 2006
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{{Addthis}}
  
 
[[Category:Projects]]
 
[[Category:Projects]]
 
[[Category:Nanorobotics]]
 
[[Category:Nanorobotics]]

Latest revision as of 12:08, 16 March 2011

Contents

[edit] Introduction

Complex wavelets are superior to real-valued wavelets because they are nearly shift-invariant. Complex wavelets yield amplitude-phase information in a similar way as the Fourier transform does. In contrast to the Fourier transform, wavelets allow to analyse the signal locally and thus can be applied to signals with a non-stationary statistic (such as images of a natural scene). In the same way as a one-dimensional signal requires complex numbers to represent the local structure of the signal, two-dimensional signals require hypercomplex numbers. Kingsbury has developed the Dual-Tree Complex Wavelet Transform which allows to recursively compute complex wavelet transforms. Analogous to one-dimensional analysis requiring complex values, two-dimensional analysis requires 4-valued complex numbers (hypercomplex values). Bülow, Kingsbury, and others already have successfully used hypercomplex numbers for analysing two-dimensional signals.

[edit] Implementation

High- and low-frequency decomposition using the dual-tree complex wavelet transform. The approximate shift-invariance leads to reduced aliasing

HornetsEye now contains an implementation of the Dual-Tree Complex Wavelet Transform. The implementation makes use of Hilbert transform pairs of wavelet bases. The wavelet transform was implemented with HornetsEye's **MultiArray** class.

[edit] Wavelet Editor

Wavelet editor

An editor for visualising linear combinations of wavelets was implemented. The code requires qt4-qtruby, and HornetsEye. The source code is part of the HornetsEye source package. You may need to compile the user interface design file using rbuic4 like this:

rbuic4 waveletEdit.ui > ui_waveletEdit.rb

You can view the source files in their current state at http://bazaar.launchpad.net/~wedesoft/hornetseye/trunk/files in the subdirectory samples/hypercomplex.

[edit] See Also

[edit] External Links

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