Difference between revisions of "OpenIGTLink/Matlab"

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<font color="red">We have moved this page to http://openigtlink.org/tutorials/matlabigtl.html</font>
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[[OpenIGTLink | &lt;&lt; OpenIGTLink]]
 
[[OpenIGTLink | &lt;&lt; OpenIGTLink]]
  
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This project is a generalization of [[Projects/Slicer3/2007_Project_Week_Slicer_Matlab_Pipeline_for_scalars_and_tensors | Slicer Matlab Pipeline project]] in the 2007 NA-MIC Project Week.
 
This project is a generalization of [[Projects/Slicer3/2007_Project_Week_Slicer_Matlab_Pipeline_for_scalars_and_tensors | Slicer Matlab Pipeline project]] in the 2007 NA-MIC Project Week.
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=Demo Videos=
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==Scenario 1: Push image data to 3D Slicer from Matlab console (1-way communication) ==
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Matlab and 3D Slicer are running on different hosts (the Matlab window is displayed using remote display). A matrix 'I' and 'M' on the Matlab console contain image data and affine transformation respectively. With just a several lines of commands on the Matlab console, the image data is transferred to the 3D Slicer through the network using OpenIGTLink.
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[[Media:OpenIGTLink_Matlab_1way.mov]]
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==Scenario 2: Request Matlab to process image data from 3D Slicer (2-way communication)==
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Matlab and 3D Slicer are running on different hosts (Matlab window is displayed using remote display). On the Matlab console, an example image processing server ('example_server.m') is running. This example server basically receives an image form external software, apply a filter and return a result. Once the OpenIGTLink connection between the 3D Slicer and the Matlab is established, the example MR image is loaded into the scene on the 3D Slicer, and then pushed to the Matlab through the OpenIGTLink connection. After a few seconds, the Matlab returns the filtered image to the 3D Slicer through the same OpenIGTLink connection. The image is visualized on the 3D Slicer.
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[[Media:OpenIGTLink_Matlab_2way.mov]]
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==Scenario 3: Send transform (4x4 matrix) from Matlab to 3D Slicer==
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Matlab and 3D Slicer are running on different hosts (Matlab window is displayed using remote display). The video demonstrates to manipulate 4x4 matrix on the Matlab console and then transfer to the 3D Slicer through the network using OpenIGTLink.
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[[Media:OpenIGTLink_Matlab_tracking.mov]]
  
 
=How does it work?=
 
=How does it work?=
 
The OpenIGTLink Matlab interface is implemented as a set of MEX Files, which are C/C++ source codes called from Matlab. Those MEX files simply receive data from Matlab, connect to the OpenIGTLink receiver, serialize the data in an appropriate format using the OpenIGTLink Library, and send it to the receiver.
 
The OpenIGTLink Matlab interface is implemented as a set of MEX Files, which are C/C++ source codes called from Matlab. Those MEX files simply receive data from Matlab, connect to the OpenIGTLink receiver, serialize the data in an appropriate format using the OpenIGTLink Library, and send it to the receiver.
  
The usage of the interface is quite simple. The following example Matlab code is sending trancking data to the receiver waiting at port #18944 in the localhost.
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The usage of the interface is quite simple. The following example Matlab code is sending trancking data to the receiver waiting at port #18944 on the localhost.
  
 
  %%% affine transform matrix
 
  %%% affine transform matrix
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  igtlclose(sd);
 
  igtlclose(sd);
  
=How to Get Started=
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=Download & Building OpenIGTLink Mex functions=
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==For Windows Users==
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*You may download mex binary files for 32-bit and 64-bit Windows built by Dr. Nicolas Herlambang, Ph.D. (Aze Ltd., Japan) from the following link.
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**[[File:OpenIGTLinkMex_Win32.zip]] (32 bit).
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**[[File:OpenIGTLinkMex_Win64.zip]] (64 bit).
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==For Linux Users==
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**[[File:OpenIGTLinkMex_Linux64.tar.gz]] (64 bit -- Built on 64-bit FC13 + Matlab 7.10.0 R2010a)
  
 
==Install the OpenIGTLink Library==
 
==Install the OpenIGTLink Library==
The instruction can be found in [[OpenIGTLink/Library]]
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The instruction can be found in [[OpenIGTLink/Library]]. We recommend to build the library as a static library. (Just to avoid a trouble that Matlab couldn't find shared objects/dynamic link library. In principle, either static or shared library works.)
  
 
==Get the Matlab OpenIGTLink interface source code==
 
==Get the Matlab OpenIGTLink interface source code==
 
The OpenIGTLink/Matlab interface is in the initial stage of development. The source code is available from NA-MIC SandBox repository at
 
The OpenIGTLink/Matlab interface is in the initial stage of development. The source code is available from NA-MIC SandBox repository at
  
   http://svn.na-mic.org/NAMICSandBox/trunk/BRPTools/MatlabIGTL
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   http://svn.na-mic.org/NAMICSandBox/trunk/MatlabIGTL
  
 
==Build MEX files==
 
==Build MEX files==
You need to have a MEX compiler or octave to the build MEX binaries.
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CMake configuration (CMakeLists.txt) comes with Matlab OpenIGTLink interface. To build the interface with CMake
To build the binaries, you may need to edit the Makefile.
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in Linux/Mac OS X environment,
 
 
First substitute the path to the OpenIGTLink Library source and binary directories installed in your system:
 
  ### OpenIGTLink Library
 
  IGTLSRC= /projects/igtdev/tokuda/igtl/OpenIGTLink
 
  IGTLBLD= /projects/igtdev/tokuda/igtl/OpenIGTLink-build
 
 
 
If you use Maltab, specify the full path to the MEX compiler. You don't need to have any options to the MEX compiler.
 
  MEX    = /local/os-exact/pkg/Matlab71-64/bin/mex
 
  MEXOPT =
 
  
If you use Octave, specify the full path to the mkoctfile program and "--mex" option.
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cd <working directory>
  MEX    = /Applications/Octave.app/Contents/Resources/bin/mkoctfile
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svn co URL: http://svn.na-mic.org/NAMICSandBox/trunk/MatlabIGTL
  MEXOPT = --mex
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mkdir MatlabIGTL-build
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cd MatlabIGTL-build
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ccmake ../MatlabIGTL
  
Now it's ready to build your MEX file. Run make. If the MEX files are successfully built, you could find:
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This will launch Curses Interface for CMake. Press 'c' to configure and check the following parameters;
  igtlclose.mex<arc-name>
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  *MEX_COMPILER = (path to Matlab's '''mex''' command or Octave's '''mkoctfile''')
  igtlopen.mex<arc-name>
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  *OpenIGTLInk_DIR = (path to binary directory of OpenIGTLink)
igtlsend.mex<arc-name>
 
  
Note that <arc-name> is the architecture name of your system.
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Then press 'g' to generate a makefile. Press 'q' to quit the CMake interface screen.
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Once you find '''Makefile''' in the directory, run make. Several files with extension *.mex (or *.mex<arc-name>) will be generated.
  
 
=Contact=
 
=Contact=
 
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If you have any question, please subscribe to OpenIGTLink ML.
We are not providing a support for this software, but questions and requests are always welcome. If you have any, please contact
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You may also contact to [[User:Tokuda|Junichi Tokuda]] for further information.
[[User:Tokuda| Junichi Tokuda]] at Brigham and Women's Hospital.
 

Latest revision as of 18:06, 7 January 2013

Home < OpenIGTLink < Matlab

We have moved this page to http://openigtlink.org/tutorials/matlabigtl.html


<< OpenIGTLink

About the project

The objective of this project is to provide OpenIGTLink interface for Matlab / Octave to support research and development in image guided therapy (IGT). Matlab and Octave are widely used for prototyping image and signal processing algorithms. They also offer many powerful function sets to handle matrix and coordinate data, which is useful to test and analyze coordinate data exported from tracking and robotic devices. The OpenIGTLink interface for Matlab / Octave allows importing and exporting several types of data that can be handled in the OpenIGTLink protocol in a Matlab / Octave environment. It provides a rapid prototyping environment, which many researchers and engineers are already familiar with.

This project is a generalization of Slicer Matlab Pipeline project in the 2007 NA-MIC Project Week.

Demo Videos

Scenario 1: Push image data to 3D Slicer from Matlab console (1-way communication)

Matlab and 3D Slicer are running on different hosts (the Matlab window is displayed using remote display). A matrix 'I' and 'M' on the Matlab console contain image data and affine transformation respectively. With just a several lines of commands on the Matlab console, the image data is transferred to the 3D Slicer through the network using OpenIGTLink.

Media:OpenIGTLink_Matlab_1way.mov


Scenario 2: Request Matlab to process image data from 3D Slicer (2-way communication)

Matlab and 3D Slicer are running on different hosts (Matlab window is displayed using remote display). On the Matlab console, an example image processing server ('example_server.m') is running. This example server basically receives an image form external software, apply a filter and return a result. Once the OpenIGTLink connection between the 3D Slicer and the Matlab is established, the example MR image is loaded into the scene on the 3D Slicer, and then pushed to the Matlab through the OpenIGTLink connection. After a few seconds, the Matlab returns the filtered image to the 3D Slicer through the same OpenIGTLink connection. The image is visualized on the 3D Slicer.

Media:OpenIGTLink_Matlab_2way.mov

Scenario 3: Send transform (4x4 matrix) from Matlab to 3D Slicer

Matlab and 3D Slicer are running on different hosts (Matlab window is displayed using remote display). The video demonstrates to manipulate 4x4 matrix on the Matlab console and then transfer to the 3D Slicer through the network using OpenIGTLink.


Media:OpenIGTLink_Matlab_tracking.mov

How does it work?

The OpenIGTLink Matlab interface is implemented as a set of MEX Files, which are C/C++ source codes called from Matlab. Those MEX files simply receive data from Matlab, connect to the OpenIGTLink receiver, serialize the data in an appropriate format using the OpenIGTLink Library, and send it to the receiver.

The usage of the interface is quite simple. The following example Matlab code is sending trancking data to the receiver waiting at port #18944 on the localhost.

%%% affine transform matrix
M = [1.0, 0.0, 0.0, 0.0;
     0.0,-1.0, 0.0, 0.0;
     0.0, 0.0, 1.0, 0.0;
     0.0, 0.0, 0.0, 1.0];

IMGDATA.Type = 'TRANSFORM';
IMGDATA.Name = 'MatlabTrans';
IMGDATA.Trans = M;

sd = igtlopen('localhost', 18944);
r = igtlsend(sd, IMGDATA);
igtlclose(sd);


For tracking data transfer:

%%% read image data
fid = fopen('igtlTestImage1.raw', 'r');
I = fread(fid, [256 256], 'uint8')';
fclose(fid);

%%% affine transform matrix
M = [1.0, 0.0, 0.0, 0.0;
     0.0,-1.0, 0.0, 0.0;
     0.0, 0.0, 1.0, 0.0;
     0.0, 0.0, 0.0, 1.0];

IMGDATA.Type = 'IMAGE';
IMGDATA.Name = 'MatlabImage';
IMGDATA.Image = I;
IMGDATA.Trans = M;

%%% send the image data through OpenIGTLink connection
sd = igtlopen('localhost', 18944);
r = igtlsend(sd, IMGDATA);
igtlclose(sd);


Download & Building OpenIGTLink Mex functions

For Windows Users

For Linux Users

Install the OpenIGTLink Library

The instruction can be found in OpenIGTLink/Library. We recommend to build the library as a static library. (Just to avoid a trouble that Matlab couldn't find shared objects/dynamic link library. In principle, either static or shared library works.)

Get the Matlab OpenIGTLink interface source code

The OpenIGTLink/Matlab interface is in the initial stage of development. The source code is available from NA-MIC SandBox repository at

 http://svn.na-mic.org/NAMICSandBox/trunk/MatlabIGTL

Build MEX files

CMake configuration (CMakeLists.txt) comes with Matlab OpenIGTLink interface. To build the interface with CMake in Linux/Mac OS X environment,

cd <working directory>
svn co URL: http://svn.na-mic.org/NAMICSandBox/trunk/MatlabIGTL
mkdir MatlabIGTL-build
cd MatlabIGTL-build
ccmake ../MatlabIGTL

This will launch Curses Interface for CMake. Press 'c' to configure and check the following parameters;

*MEX_COMPILER = (path to Matlab's mex command or Octave's mkoctfile)
*OpenIGTLInk_DIR = (path to binary directory of OpenIGTLink)

Then press 'g' to generate a makefile. Press 'q' to quit the CMake interface screen. Once you find Makefile in the directory, run make. Several files with extension *.mex (or *.mex<arc-name>) will be generated.

Contact

If you have any question, please subscribe to OpenIGTLink ML. You may also contact to Junichi Tokuda for further information.