RTK/Meetings/TrainingNov15: Difference between revisions
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= Geometry = | |||
== Real == | |||
Edit and analyze the [http://midas3.kitware.com/midas/download/item/318790/geometry.xml geometry file] obtained from a real Elekta Synergy acquisition. Compare to the projection files using the command | |||
<source lang="bash" enclose="div"> | |||
vv --sequence *his | |||
</source> | |||
(VV help: F1). | |||
== Simulated == | |||
Use the command line application rtksimulatedgeometry to generate simulated geometries and analyze the outputs. (Help: rtksimulatedgeometry -h). | |||
= Basic operators = | = Basic operators = | ||
Revision as of 02:40, 9 November 2015
Geometry
Real
Edit and analyze the geometry file obtained from a real Elekta Synergy acquisition. Compare to the projection files using the command
vv --sequence *his
(VV help: F1).
Simulated
Use the command line application rtksimulatedgeometry to generate simulated geometries and analyze the outputs. (Help: rtksimulatedgeometry -h).
Basic operators
Here is a list of the RTK command lines you will have to run during the training, along with the data you will need. To start, download the following CT data and a relevant Cone-Beam CT geometry file.
Forward projection
To forward project the CT volume, following the geometry described in geometry.xml, run
rtkforwardprojections -i muCT.mha -o projections.mha -g geometry.xml
Look at the result using vv
vv projections.mha
There are as many projections as described in the geometry.xml file. You can edit the geometry.xml file, remove all projections except one, and try again. Such a modified geometry file is available here. Run the following command line
rtkforwardprojections -i muCT.mha -o singleProjection.mha -g singleProjectionGeometry.xml
You can check with vv that the file contains only one projection
vv singleProjection.mha
Back projection
Start by back projecting a single projection. Run
rtkbackprojections -p . -r singleProjection.mha -o singleBackProjection.mha -g singleProjectionGeometry.xml
Observe the result with vv
vv singleBackProjection.mha
As you can see, the projection data seems to be smeared into the volume. Now back project all projections, by running
rtkbackprojections -p . -r projections.mha -o backProjection.mha -g geometry.xml
Look at the result with vv. In order to compare it with the original image, run
vv backProjection.mha muCT.mha --linkall
Click in one of the display windows, hit 'Ctrl + G' to center the view on the tumor. Hit 'w' to automatically compute reasonable window and level values. You can navigate between "muCT.mha" and "backProjection.mha" by hitting the 'Tab' key.
Using different forward and back projection algorithms
Both rtkforwardprojections and rtkbackprojections can use several algorithms to perform the forward or back projections. For forward projections, you can try the following command lines
rtkforwardprojections -i muCT.mha -o josephProjections.mha -g geometry.xml --fp Joseph
rtkforwardprojections -i muCT.mha -o rayCastInterpolatorProjections.mha -g geometry.xml --fp RayCastInterpolator
And for back projection
rtkbackprojections -p . -r projections.mha -o voxelBasedBackProjection.mha -g geometry.xml --bp VoxelBasedBackProjection
rtkbackprojections -p . -r projections.mha -o josephBackProjection.mha -g geometry.xml --bp Joseph
rtkbackprojections -p . -r projections.mha -o normalizedJosephBackProjection.mha -g geometry.xml --bp NormalizedJoseph
If you have a CUDA-capable graphics card, and have compiled RTK with RTK_USE_CUDA=ON, you can also try the following
rtkforwardprojections -i muCT.mha -o cudaRayCastProjections.mha -g geometry.xml --fp CudaRayCast
rtkbackprojections -p . -r projections.mha -o cudaRayCastBackProjection.mha -g geometry.xml --bp CudaRayCast
rtkbackprojections -p . -r projections.mha -o cudaBackProjection.mha -g geometry.xml --bp CudaBackProjection
3D Reconstruction
Creating a very small dataset
Various reconstruction algorithms exist, which employ forward and back projection extensively. We will now start performing real reconstructions using some of the algorithms implemented in RTK. Since these algorithms are computationally much more demanding than the standard FDK, we propose to run them with low resolution data. You will be able to re-compute them at full resolution later, since the present page will remain available to you after the training. Note that, for the regularized reconstruction techniques, you will have to re-tune the regularization parameters yourself, since they depend (among many things) on resolution.
Start by downloading the cone beam CT projection data here, and extract it. It contains 644 projections, each one in a ".his" file. You can view them in vv by typing
vv --sequence *.his
RTK has a collection of tools to convert and preprocess commercial CBCT projection data, most of which are combined in the application "rtkprojections". To convert and preprocess these projections, run
rtkprojections -p . -r .*.his -o downsampledProjections.mha --binning "4, 4"
The '--binning "4, 4"' option downsamples the projections by 4 along both axes. Since this is not enough to reach acceptable reconstruction times for the training, we will build a sub-dataset by selecting only one projection out of 5. You can do this by running
rtksubselect -p . -r downsampledProjections.mha -g geometry.xml --out_geometry subGeometry.xml --out_proj subProjections.mha -s 5
This creates a new geometry file and a new projections file, from which even a laptop should be able to perform iterative reconstruction in reasonable time.
Unregularized 3D iterative reconstruction algorithms
The most popular iterative reconstruction algorithm is the Simultaneous Algebraic Reconstruction Technique (SART). Try it by running
rtksart -p . -r subProjections.mha -g subGeometry.xml -o SART.mha --dimension 128 --spacing 3
Another popular technique uses the conjugate gradient algorithm
rtkconjugategradient -p . -r subProjections.mha -g subGeometry.xml -o CG.mha --dimension 128 --spacing 3 -n 10
You can compare the results by running
vv SART.mha CG.mha --linkall
The SART reconstruction should be sharper than the conjugate gradient one. If you are interested in understanding the reasons for this difference, try running
rtksart -p . -r subProjections.mha -g subGeometry.xml -o OSSART_10projsPerSubset.mha --dimension 128 --spacing 3 --nprojspersubset 10
The differences in image quality (sharpness, contrast, ...) and convergence speed, stability, ... between the various algorithms may be discussed briefly during the training.
Regularized 3D iterative reconstruction algorithms
RTK also includes algorithms that perform regularization during the reconstruction. You can try for example
rtkadmmtotalvariation -p . -r subProjections.mha -g subGeometry.xml -o admmTV.mha --dimension 128 --spacing 3 -n 10 --beta 1000 --alpha 1
and
rtkadmmwavelets -p . -r subProjections.mha -g subGeometry.xml -o admmWavelets.mha --dimension 128 --spacing 3 -n 10 --beta 1000 --alpha 1
Note that these algorithms have little interest when working with such low resolution data, since most of the noise and artifacts they are meant to remove have already been eliminated by undersampling.
4D Iterative reconstruction
The 4D reconstruction applications may take a long time to compute. If you do not have a CUDA-capable GPU, you may want to skip them and take the reconstruction results directly from the USB key you received at the beginning of the training. If you do have a CUDA-capable GPU and have compiled RTK with RTK_USE_CUDA=ON, you can add
--fp CudaRayCast --bp CudaVoxelBased
to the reconstruction command lines in order to use it.
Extracting respiratory phase
RTK includes a tool to extract the phase of respiratory motion from the projection data. It uses an intermediate image built from the stack of projections, called the "shroud". Run
rtkamsterdamshroud -p . -r .*.his -o shroud.mhd
and open the shroud image with vv:
vv shroud.mhd
You will notice that a periodic signal is visible in the image. Before we try to retrieve this signal's phase, we need to remove the parts of the image affected by low frequency noise. Try
rtkamsterdamshroud -p . -r .*.his -o cshroud.mhd --lowercrop "0, 270, 0" --upper "0, 112, 0"
The cropped shroud can be viewed with vv:
vv cshroud.mhd
This cropped shroud will be used to extract a phase signal, with another RTK command. Run
rtkextractshroudsignal -i cshroud.mhd -o signal.txt -p cphase.txt
If you have Python installed, you can download this script and run it from your working directory. It will generate an image with the cropped shroud in background and the detected minima in foreground, in red.
Unregularized iterative 4D reconstruction
RTK includes several algorithms for 4D reconstruction. Similarly to 3D, you can try them with the following commands
rtkfourdsart -p . -r downsampledProjections.mha -g geometry.xml -o 4DSART.mha --signal cphase.txt --dimension 128 --spacing 3
rtkfourdconjugategradient -p . -r downsampledProjections.mha -g geometry.xml -o 4DCG.mha --signal cphase.txt --dimension 128 --spacing 3
Regularized iterative 4D reconstruction
Just like in 3D reconstruction, regularity conditions can be added in 4D reconstruction. Actually, 4D reconstruction even allows more regularization: since the whole respiratory cycle is reconstructed at once, regularization along time can be applied. RTK includes an application to perform regularized 4D reconstruction, called ROOSTER. It requires a motion mask, which you can download here. You can try ROOSTER by running
rtkfourdrooster -p . -r downsampledProjections.mha -g geometry.xml -o 4DROOSTER.mha --signal cphase.txt --dimension 128 --spacing 3 --gamma_time 0.0005 --gamma_space 0.0001 --motionmask mm_50.mha