Software/Geant4/Tutorials/Basic/Monoenergetic Proton Pencil Beam: Difference between revisions
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== | == Monoenergetic Proton Pencil Beam == | ||
This example shows the dose distribution in water along the incident proton beam. | This example shows the dose distribution in water along the incident proton beam. | ||
Line 16: | Line 16: | ||
The image shows the water box divided into slices using class <code>G4PVReplica</code>. | The image shows the water box divided into slices using class <code>G4PVReplica</code>. | ||
Protons are in blue, photons are in green. | Protons are in blue, photons are in green. | ||
== Running the Tutorial == | == Running the Tutorial == | ||
Line 39: | Line 39: | ||
<pre> | <pre> | ||
[username@plus1 ProtonPBFolder]$ source /unix/pbt/software/ | [username@plus1 ProtonPBFolder]$ source /unix/pbt/software/scripts/pbt.sh | ||
</pre> | </pre> | ||
Line 45: | Line 45: | ||
<pre> | <pre> | ||
[username@plus1 ProtonPBFolder]$ cp - | [username@plus1 ProtonPBFolder]$ cp -rv /unix/pbt/tutorials/basic/ProtonPB . | ||
[username@plus1 ProtonPBFolder]$ mv ProtonPB ProtonPB_source | [username@plus1 ProtonPBFolder]$ mv ProtonPB ProtonPB_source | ||
Line 478: | Line 478: | ||
.q | .q | ||
</pre> | </pre> | ||
=== Plotting the dose distribution === | |||
Folder <code>RootScripts</code> contains several ROOT scripts which plot dose deposition in data and simulation. | Folder <code>RootScripts</code> contains several ROOT scripts which plot dose deposition in data and simulation. | ||
Line 837: | Line 839: | ||
== Files == | == Files == | ||
[[List of | [[Software/Geant4/Tutorials/Basic/Proton Pencil Beam Files|List of files for Mononenergetic Proton Pencil Beam simulation]]. |
Latest revision as of 12:27, 6 November 2024
Monoenergetic Proton Pencil Beam
This example shows the dose distribution in water along the incident proton beam. The beam hits the water cube surface and deposits a dose under the surface of the water. The volume of the water cube is divided into slices perpendicular to the incident beam. At each slice the deposited dose and energy is computed.
The slices are created using class G4PVReplica
.
The energy and the dose are scored using classes G4UserSteppingAction
and G4UserRunAction
.
Alternatively, the energy and the dose are scored using class G4ScoringManager
by defining two scoring meshes in longitudinal and lateral direction of the beam.
More information about the scoring meshes can be found here.
The protons are generated using G4ParticleGun
class.
There is an option to chose among several EM
and the QGSP_BIC_EMY
physics lists.
The image shows the water box divided into slices using class G4PVReplica
.
Protons are in blue, photons are in green.
Running the Tutorial
All the source files for the tutorial can be found in http://www.hep.ucl.ac.uk/pbt/wikiData/code/ProtonPB/.
The corresponding data files are available from http://www.hep.ucl.ac.uk/pbt/wikiData/data/ProtonPB/.
Create folder ProtonPBFolder
ssh -X username@plus1.hep.ucl.ac.uk username@plus1.hep.ucl.ac.uk's password: type your password here [username@plus1 ~]$ mkdir ProtonPBFolder [username@plus1 ~]$ cd ProtonPBFolder
Setup Your Environment
[username@plus1 ProtonPBFolder]$ source /unix/pbt/software/scripts/pbt.sh
Copy the Code to Your Working Directory and Rename It
[username@plus1 ProtonPBFolder]$ cp -rv /unix/pbt/tutorials/basic/ProtonPB . [username@plus1 ProtonPBFolder]$ mv ProtonPB ProtonPB_source
Create the Build Directory
[username@plus1 ProtonPBFolder]$ mkdir ProtonPB_build
Compile the Code with Make
and Cmake
[username@plus1 ProtonPBFolder]$ cd ProtonPB_build [username@plus1 ProtonPB_build]$ cmake -DGeant4_DIR=/unix/pbt/software/dev /home/username/ProtonPBFolder/ProtonPB_source [username@plus1 ProtonPB_build]$ make
Run Macro proton.mac
[username@plus1 ProtonPB_build]$ ./protonPB proton.mac
Analysing the Data
The macro produces a root file Proton.root
with two histograms.
The first histogram shows the energy deposition in water box along the beam line, the second histogram shows zoomed energy deposition around the peak.
The macro also produces several text files.
- The data in files
DoseFile.txt
andPlotDose.txt
was created using classesG4UserSteppingAction
andG4UserRunAction
. The fileDoseFile.txt
contains energy and dose deposition for every layer. The filePlotDose.txt
contains only depth vs dose for each layer. These text files can be analyzed with MATLAB or ROOT.
- The files
DoseLongitudinalMesh.txt
,EnergyLongitudinalMesh.txt
,DoseLateralMesh.txt
andEnergyLateralMesh.txt
contain information about the dose and energy deposition in voxels in longitudinal and lateral direction of the beam. The data was created using classG4ScoringManager
and commands/score/
in proton.mac. These text files can be analyzed with MATLAB or ROOT.
- The two ways to record data should give similar result.
Text files
This is output from DoseFile.txt
with physics process QGSP_BIC_EMY
and incident proton energy of 62 MeV.
Use your favorite editor pico
, vi
, emacs
etc to open text files.
For example, open this text file with editor pico
:
[username@plus1 ProtonPB_build]$ pico DoseFile.txt
DoseFile.txt
Layers : x[mm] Edep Edep/Ebeam[%] Dose Dose/MaxDose[%] layer 1: 0.8 5.17382 GeV 1.39081 6.47608e-07 Gy 17.3315 layer 2: 1.6 5.24175 GeV 1.40907 6.5611e-07 Gy 17.5591 layer 3: 2.4 5.29862 GeV 1.42436 6.63229e-07 Gy 17.7496 layer 4: 3.2 5.41481 GeV 1.45559 6.77772e-07 Gy 18.1388 layer 5: 4 5.43787 GeV 1.46179 6.80658e-07 Gy 18.216 layer 6: 4.8 5.52101 GeV 1.48414 6.91065e-07 Gy 18.4946 layer 7: 5.6 5.64633 GeV 1.51783 7.06751e-07 Gy 18.9144 layer 8: 6.4 5.63969 GeV 1.51605 7.0592e-07 Gy 18.8921 layer 9: 7.2 5.71744 GeV 1.53695 7.15652e-07 Gy 19.1526 layer 10: 8 5.78086 GeV 1.55399 7.2359e-07 Gy 19.365 layer 11: 8.8 5.94371 GeV 1.59777 7.43975e-07 Gy 19.9106 layer 12: 9.6 6.02518 GeV 1.61967 7.54172e-07 Gy 20.1835 layer 13: 10.4 6.10292 GeV 1.64057 7.63903e-07 Gy 20.4439 layer 14: 11.2 6.18071 GeV 1.66148 7.7364e-07 Gy 20.7045 layer 15: 12 6.2621 GeV 1.68336 7.83827e-07 Gy 20.9771 layer 16: 12.8 6.37762 GeV 1.71441 7.98286e-07 Gy 21.3641 layer 17: 13.6 6.52458 GeV 1.75392 8.16682e-07 Gy 21.8564 layer 18: 14.4 6.67805 GeV 1.79517 8.35892e-07 Gy 22.3705 layer 19: 15.2 6.86252 GeV 1.84476 8.58982e-07 Gy 22.9884 layer 20: 16 6.95226 GeV 1.86889 8.70215e-07 Gy 23.289 layer 21: 16.8 7.11679 GeV 1.91312 8.90809e-07 Gy 23.8402 layer 22: 17.6 7.15125 GeV 1.92238 8.95122e-07 Gy 23.9556 layer 23: 18.4 7.43274 GeV 1.99805 9.30356e-07 Gy 24.8986 layer 24: 19.2 7.58811 GeV 2.03981 9.49804e-07 Gy 25.419 layer 25: 20 7.8156 GeV 2.10097 9.78279e-07 Gy 26.1811 layer 26: 20.8 7.94754 GeV 2.13643 9.94794e-07 Gy 26.6231 layer 27: 21.6 8.35363 GeV 2.2456 1.04562e-06 Gy 27.9834 layer 28: 22.4 8.44564 GeV 2.27033 1.05714e-06 Gy 28.2917 layer 29: 23.2 8.74817 GeV 2.35166 1.09501e-06 Gy 29.3051 layer 30: 24 9.08194 GeV 2.44138 1.13679e-06 Gy 30.4232 layer 31: 24.8 9.50886 GeV 2.55615 1.19022e-06 Gy 31.8533 layer 32: 25.6 9.93302 GeV 2.67017 1.24332e-06 Gy 33.2741 layer 33: 26.4 10.5627 GeV 2.83943 1.32213e-06 Gy 35.3834 layer 34: 27.2 11.1563 GeV 2.99902 1.39644e-06 Gy 37.3721 layer 35: 28 12.0025 GeV 3.22647 1.50235e-06 Gy 40.2065 layer 36: 28.8 13.1124 GeV 3.52485 1.64128e-06 Gy 43.9247 layer 37: 29.6 14.5158 GeV 3.90209 1.81694e-06 Gy 48.6257 layer 38: 30.4 16.8932 GeV 4.54119 2.11452e-06 Gy 56.5898 layer 39: 31.2 20.9827 GeV 5.64051 2.62641e-06 Gy 70.289 layer 40: 32 29.8521 GeV 8.02475 3.73658e-06 Gy 100 layer 41: 32.8 14.922 GeV 4.0113 1.86779e-06 Gy 49.9866 layer 42: 33.6 330.005 MeV 0.088711 4.13067e-08 Gy 1.10547 layer 43: 34.4 2.92265 MeV 0.000785658 3.65828e-10 Gy 0.00979044 layer 44: 35.2 864.413 keV 0.000232369 1.08199e-10 Gy 0.00289566 layer 45: 36 673.958 keV 0.000181172 8.43594e-11 Gy 0.00225766 layer 46: 36.8 1.18851 MeV 0.000319491 1.48765e-10 Gy 0.00398132 layer 47: 37.6 3.81319 MeV 0.00102505 4.77297e-10 Gy 0.0127736 layer 48: 38.4 4.58219 MeV 0.00123177 5.73552e-10 Gy 0.0153496 layer 49: 39.2 7.29449 MeV 0.00196088 9.13052e-10 Gy 0.0244355 layer 50: 40 0 eV 0 0 Gy 0 The run consists of 6000 proton of 62 MeV through 4 cm of Water (density: 1 g/cm3 ) divided into 50 slices. Edep is the deposited energy in every slice. Total incident energy(Ebeam)= 372 GeV Total energy deposit= 367.368 GeV Dose is the deposited dose in every slice. MaxDose is the highest dose value from all slices.
PlotDose.txt
The corresponding PlotDose.txt
is:
0.8 17.3315 1.6 17.5591 2.4 17.7496 3.2 18.1388 4 18.216 4.8 18.4946 5.6 18.9144 6.4 18.8921 7.2 19.1526 8 19.365 8.8 19.9106 9.6 20.1835 10.4 20.4439 11.2 20.7045 12 20.9771 12.8 21.3641 13.6 21.8564 14.4 22.3705 15.2 22.9884 16 23.289 16.8 23.8402 17.6 23.9556 18.4 24.8986 19.2 25.419 20 26.1811 20.8 26.6231 21.6 27.9834 22.4 28.2917 23.2 29.3051 24 30.4232 24.8 31.8533 25.6 33.2741 26.4 35.3834 27.2 37.3721 28 40.2065 28.8 43.9247 29.6 48.6257 30.4 56.5898 31.2 70.289 32 100 32.8 49.9866 33.6 1.10547 34.4 0.00979044 35.2 0.00289566 36 0.00225766 36.8 0.00398132 37.6 0.0127736 38.4 0.0153496 39.2 0.0244355 40 0
The files DoseLongitudinalMesh.txt
and EnergyLongitudinalMesh.txt
contain information about the dose and energy deposition in 50 voxels along the beam.
DoseLongitudinalMesh.txt
# mesh name: waterMeshlongitudinal # primitive scorer name: doseDeposit # iX, iY, iZ, value [Gy] 0,0,0,6.398582855930675e-07 1,0,0,6.476076943270951e-07 2,0,0,6.561104727924428e-07 3,0,0,6.632288576514804e-07 4,0,0,6.777723406342788e-07 5,0,0,6.806579456409969e-07 6,0,0,6.91064665975597e-07 7,0,0,7.067512545709638e-07 8,0,0,7.059200031350208e-07 9,0,0,7.156519176900015e-07 10,0,0,7.235903386590427e-07 11,0,0,7.439747389552145e-07 12,0,0,7.541720785591247e-07 13,0,0,7.639027568851979e-07 14,0,0,7.736399498415839e-07 15,0,0,7.838271332286684e-07 16,0,0,7.982864751716507e-07 17,0,0,8.166815318022948e-07 18,0,0,8.35891621887706e-07 19,0,0,8.589818300723569e-07 20,0,0,8.702146985960477e-07 21,0,0,8.908094582985716e-07 22,0,0,8.951224309882678e-07 23,0,0,9.303558877909548e-07 24,0,0,9.498037872001912e-07 25,0,0,9.782791267955695e-07 26,0,0,9.947936277972093e-07 27,0,0,1.045624447589806e-06 28,0,0,1.057141333117292e-06 29,0,0,1.095009220830727e-06 30,0,0,1.136786796980433e-06 31,0,0,1.190224735866411e-06 32,0,0,1.243315989674068e-06 33,0,0,1.322130956487186e-06 34,0,0,1.396440433021823e-06 35,0,0,1.50234984419867e-06 36,0,0,1.641284907129354e-06 37,0,0,1.816941697430821e-06 38,0,0,2.11452442916524e-06 39,0,0,2.62640665908421e-06 40,0,0,3.736584034770657e-06 41,0,0,1.867790510876118e-06 42,0,0,4.130671695136958e-08 43,0,0,3.658280235043075e-10 44,0,0,1.081986690905131e-10 45,0,0,8.435936307778899e-11 46,0,0,1.48765431607862e-10 47,0,0,4.77297093105983e-10 48,0,0,5.735524713083603e-10 49,0,0,9.130516230902128e-10
EnergyLongitudinalMesh.txt
# mesh name: waterMeshlongitudinal # primitive scorer name: energyDeposit # iX, iY, iZ, value [MeV] 0,0,0,5111.912527768401 1,0,0,5173.82357976574 2,0,0,5241.753402253778 3,0,0,5298.623120998874 4,0,0,5414.812931353903 5,0,0,5437.86641165753 6,0,0,5521.007077722527 7,0,0,5646.32931010448 8,0,0,5639.688332367972 9,0,0,5717.437885750247 10,0,0,5780.858981508537 11,0,0,5943.712653315673 12,0,0,6025.180549012026 13,0,0,6102.920225997912 14,0,0,6180.711949227533 15,0,0,6262.098705563481 16,0,0,6377.616302015511 17,0,0,6524.576843992425 18,0,0,6678.048796107832 19,0,0,6862.519525245148 20,0,0,6952.260398532138 21,0,0,7116.794659477272 22,0,0,7151.251569109977 23,0,0,7432.736318595246 24,0,0,7588.108160872322 25,0,0,7815.601417563028 26,0,0,7947.537951731407 27,0,0,8353.632098427806 28,0,0,8445.642021147274 29,0,0,8748.173587841 30,0,0,9081.94017289281 31,0,0,9508.862939073984 32,0,0,9933.015992281295 33,0,0,10562.67919317931 34,0,0,11156.34743594843 35,0,0,12002.47173877234 36,0,0,13112.44234434682 37,0,0,14515.7876899454 38,0,0,16893.21551834444 39,0,0,20982.71039991735 40,0,0,29852.0643843804 41,0,0,14922.02559031455 42,0,0,330.0048285988424 43,0,0,2.922648496498087 44,0,0,0.8644134872755548 45,0,0,0.6739581164479411 46,0,0,1.188506721969284 47,0,0,3.813189646289314 48,0,0,4.582186601985135 49,0,0,7.294490257710744
The files DoseLateralMesh.txt
and EnergyLateralMesh.txt
contain information about the dose and energy deposition in 50 voxels in direction perpendicular to the beam at its peak location along the beam.
DoseLateralMesh.txt
# mesh name: waterMeshlateral # primitive scorer name: doseDeposit # iX, iY, iZ, value [Gy] 0,0,0,0 0,0,1,0 0,0,2,0 0,0,3,0 0,0,4,0 0,0,5,0 0,0,6,0 0,0,7,0 0,0,8,0 0,0,9,8.892767522638671e-11 0,0,10,8.21852079266635e-10 0,0,11,0 0,0,12,0 0,0,13,8.318919310499272e-09 0,0,14,1.595723831016101e-09 0,0,15,0 0,0,16,2.546870274558055e-08 0,0,17,5.784197150675933e-08 0,0,18,1.230136624294735e-07 0,0,19,1.494748043820479e-07 0,0,20,2.215227319180893e-07 0,0,21,5.986605482048514e-07 0,0,22,1.329975409856811e-06 0,0,23,1.476881959416276e-05 0,0,24,5.974330866809595e-05 0,0,25,5.920917640298571e-05 0,0,26,1.639379722918268e-05 0,0,27,1.739367160863735e-06 0,0,28,3.982482450957319e-07 0,0,29,2.221785043134072e-07 0,0,30,1.39961928308002e-07 0,0,31,1.233101954534728e-07 0,0,32,5.621640994750944e-08 0,0,33,7.942616647408834e-08 0,0,34,4.494378494527077e-09 0,0,35,5.106873601769217e-08 0,0,36,0 0,0,37,0 0,0,38,3.322392221862852e-09 0,0,39,5.270936869417144e-10 0,0,40,0 0,0,41,0 0,0,42,0 0,0,43,0 0,0,44,0 0,0,45,2.717977576808592e-10 0,0,46,1.562629353086799e-10 0,0,47,0 0,0,48,0 0,0,49,0
EnergyLateralMesh.txt
# mesh name: waterMeshlateral # primitive scorer name: energyDeposit # iX, iY, iZ, value [MeV] 0,0,0,0 0,0,1,0 0,0,2,0 0,0,3,0 0,0,4,0 0,0,5,0 0,0,6,0 0,0,7,0 0,0,8,0 0,0,9,0.03552274834057498 0,0,10,0.3282942515999153 0,0,11,0 0,0,12,0 0,0,13,3.323047368326242 0,0,14,0.6374224438673245 0,0,15,0 0,0,16,10.17364184871573 0,0,17,23.10535828274578 0,0,18,49.13862148999507 0,0,19,59.7086997473273 0,0,20,88.48872117268637 0,0,21,239.1389175661426 0,0,22,531.2674784674697 0,0,23,5899.502718307062 0,0,24,23864.85999378014 0,0,25,23651.49732590654 0,0,26,6548.610787768303 0,0,27,694.8017225225892 0,0,28,159.0828968776824 0,0,29,88.75067379551463 0,0,30,55.90871844889415 0,0,31,49.25707356871391 0,0,32,22.45601696088681 0,0,33,31.72730779403615 0,0,34,1.795309230809683 0,0,35,20.39974454532298 0,0,36,0 0,0,37,0 0,0,38,1.327151558673589 0,0,39,0.2105510612469108 0,0,40,0 0,0,41,0 0,0,42,0 0,0,43,0 0,0,44,0 0,0,45,0.10857141290437 0,0,46,0.06242026356585469 0,0,47,0 0,0,48,0 0,0,49,0
Root file
Open Proton.root
file in the following way:
[username@plus1 ProtonPB_build]$ root -l Proton.root root [1] new TBrowser Select ROOT Files and Proton.root
The energy deposition along the beam in the absorber
The energy deposition along the beam zoomed around the peak
You can close your ROOT session by typing
.q
Plotting the dose distribution
Folder RootScripts
contains several ROOT scripts which plot dose deposition in data and simulation.
You can use script PlotSimulation.C
to plot the dose deposition along the absorber.
This script uses PlotDose.txt
.
Copy the script to your current ProtonPB_build directory:
cp /home/username/ProtonPBFolder/ProtonPB_source/RootScripts/PlotSimulation.C .
Then run the script in the following way:
[username@plus1 ProtonPB_build]$ root -l root [1] .x PlotSimulation.C
This will create Simulation.root
file with the following plot:
You can also plot the file PlotDose.txt
using MATLAB.
Similarly to the previous example first copy the text file to your computer.
In the terminal at your computer write:
scp username@plus1.hep.ucl.ac.uk:/home/username/ProtonPBFolder/ProtonPB_build/PlotDose.txt .
Then, open MATLAB and follow the procedure:
- Import the file: Chose 'HOME' tab and 'Import Data'.
- In the 'Import Data' window select the 'PlotDose.txt' file choosing the right path.
- In the opened window select the data points in the 'IMPORT' tab. If you like, you can change the name of the variables. For example, 'x' instead of 'VarName1' and 'Dose' instead of 'VarName2'. Then, press 'Import Selection'/'Import Data'.
- Close the Import Window and in the Command Window type plot(x,Dose). Press Enter.
This plot will be created with added axis labels and a legend:
You can also plot the data in DoseLongitudinalMesh.txt
and DoseLateralMesh.txt
which were created using commands /score/
in the macro proton.mac
.
The file DoseLongitudinalMesh.txt
will be used later to compare with data from the Clatterbridge Cancer Center.
Now, use script PlotLateralDoseMesh.C
to plot the lateral dose distribution.
Before running the script substitude the commas in DoseLateralMesh.txt
with spaces.
Remove also the header in the text file.
Then, save the text file as DoseLateralMesh_Mod.txt
.
[username@plus1 ProtonPB_build]$ cp /home/username/ProtonPBFolder/ProtonPB_source/RootScripts/PlotLateralDoseMesh.C . [username@plus1 ProtonPB_build]$ root -l root [1] .x PlotLateralDoseMesh.C
This will create LateralDose_Mesh.root
file with the following plot:
Run with different settings
You can change the physics process, incident proton energy and number of slices etc. by
modifying the macro proton.mac
.
Open the macro with editor pico
:
[username@plus1 ProtonPB_build]$ pico proton.mac
This is the content of the macro:
# proton.mac # /control/verbose 2 /run/verbose 2 /tracking/verbose 0 /run/particle/verbose 1 /run/particle/dumpList # # set geometry /protonPB/det/setSizeX 4 cm /protonPB/det/setSizeYZ 4 cm /protonPB/det/setSliceSizeYZ 4 cm /protonPB/det/sliceNumber 50 # # define longitudinal scoring mesh # along the beam /score/create/boxMesh waterMeshlongitudinal /score/mesh/boxSize 2. 2. 2. cm /score/mesh/nBin 50 1 1 /score/mesh/translate/xyz 0. 0. 0. cm /score/quantity/energyDeposit energyDeposit /score/quantity/doseDeposit doseDeposit /score/close # # define lateral scoring mesh # centered at the Bragg peak /score/create/boxMesh waterMeshlateral /score/mesh/boxSize 0.1 2. 2. cm /score/mesh/nBin 1 1 50 /score/mesh/translate/xyz 1.2 0. 0. cm /score/quantity/energyDeposit energyDeposit /score/quantity/doseDeposit doseDeposit /score/close # # set physics process /protonPB/phys/addPhysics QGSP_BIC_EMY #/protonPB/phys/addPhysics emlivermore #/protonPB/phys/addPhysics empenelope # # production tresholds (recommended range #cut off not bigger than 10% of slice thickness) /protonPB/phys/setCuts 0.2 mm #/protonPB/phys/setGCut 1 um #/protonPB/phys/setECut 1 um #/protonPB/phys/setPCut 1 um # # initialize /run/initialize # # visualisation #/control/execute visualisation.mac # /gun/particle proton # particle energy used in Clatterbridge Centre /gun/energy 62 MeV # # beam size #/photonPB/gun/rndm 3 mm # # step limit (recommended not bigger than 5% of # slice thickness) /protonPB/stepMax 0.1 mm # /protonPB/event/printModulo 50 # # output file /analysis/setFileName Proton # # histogram /analysis/h1/set 2 50 25 35 mm # number of events /run/beamOn 6000 # # drawing projections #/score/drawProjection waterMeshlongitudinal doseDeposit #/score/drawProjection waterMeshlateral doseDeposit # # dump scores to a file /score/dumpQuantityToFile waterMeshlongitudinal doseDeposit DoseLongitudinalMesh.txt /score/dumpQuantityToFile waterMeshlongitudinal energyDeposit EnergyLongitudinalMesh.txt /score/dumpQuantityToFile waterMeshlateral doseDeposit DoseLateralMesh.txt /score/dumpQuantityToFile waterMeshlateral energyDeposit EnergyLateralMesh.txt
Change dimensions of the water box
The default size is 4x4x4 cm. You can change the dimensions by modifying the lines
/protonPB/det/setSizeX 4 cm /protonPB/det/setSizeYZ 4 cm
Change the physics process
The default physics process is QGSP_BIC_EMY
.
This is a physics list recommended for proton therapy.
You can check what will be the dose deposition if you change the physics list.
In proton.mac
change
/photonPB/phys/addPhysics QGSP_BIC_EMY
to
/photonPB/phys/addPhysics emlivermore
Change the incident proton energy
The default energy is 62 MeV.
This is one of the energies used in radiotherapy.
In proton.mac
you can change the value of 62 MeV
/gun/energy 62 MeV
to, for example, 50 MeV
/gun/energy 50 MeV
Change the diameter of the beam
You can set the diameter of the beam with the command:
/protonPB/gun/rndm 3 mm
Change the number of slices
You can change the number of slices.
The default number is 50.
Keep in mind that if you want to increase the number of slices you need to modify the file DetectorConstruction.hh in /ProtonPB_source/include/
.
In DetectorConstruction.hh set MaxLayer to value bigger than the number of your slices.
The default value is MaxLayer=60.
For example, if you want to have 55 slices you do not need to modify MaxLayer.
Then, only in proton.mac
change the number of slices:
/protonPB/det/sliceNumber 55
Modify the mesh
You can change the size of the mesh (longitudinal and lateral) and the number of voxels by modifying their corresponding lines
/score/mesh/boxSize 2. 2. 2. cm /score/mesh/nBin 30 1 1
After modifications in proton.mac
After modifying the macro proton.mac
you can run it:
[username@plus1 ProtonPB_build]$ ./protonPB proton.mac
If you modify files in directory ProtonPB_source (for example you change the value of MaxLayer) you need to compile the code. In directory PhotonPB_build do:
[username@plus1 ProtonPB_build]$ make
then run the macro proton.mac
.
Visualisation
If you want to use visualisation, in macro proton.mac
uncomment the line /control/execute visualisation.mac
.
This will run macro visualisation.mac
with a specific visualisation setup.
If you uncomment the lines /score/drawProjection waterMeshlongitudinal doseDeposit
and /score/drawProjection waterMeshlateral doseDeposit
you will draw the dose projections.
In this example, we use DAWN
event display.
Before running the visualisation look at this DAWN tutorial.
To run the visualisation, first uncomment lines /control/execute visualisation.mac
and /score/drawProjection waterMeshlongitudinal doseDeposit
.
Then, run the proton.mac
:
[username@plus1 ProtonPB_build]$ ./protonPB proton.mac
In addition to the text files the code will create two .prim files, g4_00.prim
and g4_01.prim
.
The first file contains detector geometry and particle interactions.
The second file contains dose projections.
While running the proton.mac
you will be asked to open g4_00.prim in DAWN.
In the opened window press OK.
This will create your first visualisation:
The second file g4_01.prim will not open automatically. It will be created after the running is finished. Open the file in the following way:
[username@plus1 ProtonPB_build]$ dawn g4_01.prim
In the opened window press OK and this will create the image:
You can modify the .prim files in DAWN. For example, in the DAWN display change the polar and azimuthal angles. 1) (polar angle, azimuthal angle) = (0,90) will create this image:
2) (polar angle, azimuthal angle) = (90,0) will create this image:
Now, in proton.mac
macro uncomment /score/drawProjection waterMeshlateral doseDeposit
and comment /score/drawProjection waterMeshlongitudinal doseDeposit
.
Run proton.mac
with the new settings.
The image with the lateral dose projections will look like that:
Data from The Clatterbridge Cancer Centre
The file ClatterbridgeBraggPeak.txt
contains Bragg Peak data from the Clatterbridge Cancer Center.
The first column represents the values in mm in depth, the second column represents the normalized values of deposited dose and normalized at the peak.
You can use script PlotData.C
from folder RootScripts
to plot the data: these are available in the directory http://www.hep.ucl.ac.uk/pbt/wikiData/code/ProtonPB/.
Copy files ClatterbridgeData.txt
and PlotData.C
to your current ProtonPB_build directory and run the script:
[username@plus1 ProtonPB_build]$ cp /home/username/ProtonPBFolder/ProtonPB_source/RootScripts/PlotData.C . [username@plus1 ProtonPB_build]$ cp /home/username/ProtonPBFolder/ProtonPB_source/RootScripts/ClatterbridgeData.txt . [username@plus1 ProtonPB_build]$ root -l root [1] .x PlotData.C
This will create ClatterbridgeData.root
file with the following plot:
Comparison between data and simulation
The scripts PlotDataAndSim.C
and PlotDataAndSimMesh.C
in folder RootScripts
compare data with simulation.
You can use script PlotDataAndSim.C
to compare data (ClatterbridgeData.txt
) and simulation (PlotDose.txt
).
Both text files must be in the folder where you run the script.
[username@plus1 ProtonPB_build]$ cp /home/username/ProtonPBFolder/ProtonPB_source/RootScripts/PlotDataAndSim.C . [username@plus1 ProtonPB_build]$ root -l root [1] .x PlotDataAndSim.C
This will create BraggPeakComparison.root
file with the following plot:
You can also compare data (ClatterbridgeData.txt) with simulation done with scoring mesh (DoseLongitudinalMesh.txt
).
This can be done with script PlotDataAndSimMesh.C
.
This script works only if before running it you substitute the commas in DoseLongitudinalMesh.txt
with spaces.
Remove also the header in the text file.
Save the new text file as DoseLongitudinalMesh_Mod.txt
.
[username@plus1 ProtonPB_build]$ cp /home/username/ProtonPBFolder/ProtonPB_source/RootScripts/PlotDataAndSimMesh.C . [username@plus1 ProtonPB_build]$ root -l root [1] .x PlotDataAndSimMesh.C
This creates BraggPeakComparison_Mesh.root
file with the following plot:
Files
List of files for Mononenergetic Proton Pencil Beam simulation.