Software tutorial at IFT: Difference between revisions
Line 525: | Line 525: | ||
TRandom3 *gRandom = new TRandom3(0); // use #import <TRandom3.h> | TRandom3 *gRandom = new TRandom3(0); // use #import <TRandom3.h> | ||
cf->diffuseFrame(gRandom); | cf->diffuseFrame(gRandom); | ||
==== Inverse pixel diffusion calculation (MC and exp. data) ==== | |||
This process has been inversed in a Python script, and performed with a large number of input cluster sizes. The result is a parameterization between the proton's energy loss in a layer, and the number of activated pixels: | |||
=== Cluster identification === | === Cluster identification === |
Revision as of 09:49, 19 March 2017
Introduction and overview
This page is meant as a recipe for the software day at IFT, March 20 2017. We have decided that this should take place on Monday, March 20 between 09.00 am and 3.00 pm at the Department of Physics and Technology (our usual meeting room in the 5th floor).
There are certain steps you need to take prior to the meeting. We do not wish to loose time on installation and configuration of the software needed. Thus, it is imperative that you come with your laptops which already have the following installed and configured properly:
Agenda for the day is as follows:
- An introduction to GATE macros, i.e. GATE input scripts
- Setting up a simple simulation geometry in GATE using a proton bencil beam and a water phantom
- Running short simulations
- Examination of the GATE-output files
We think that the above mentioned mini introduction to GATE should take no longer than 1 – 1.5 hours. Rest of the day, we will focus on a more in-depth review of the analysis code written by Helge P.
- Setting up a tracking calorimeter geometry in GATE
- Running short simulations with the detector geometry
- Using the results of the MC simulations, a short «hands-on» introduction to Helge P.’s analysis code written in the Root framework
- A review of all the different modules in the above mentioned analysis code
The final goals of the day will be:
- Setting up a GATE simulation of an example tracking calorimeter including geometry, material specifications and proton beam definition
- Being able to work with the GATE output files (identifying primary protons, secondary particles, calculating deposited dose etc…)
- Being able to run a complete analysis using the Root-analysis code written by Helge P.
As always, check the User guide and tutorial for the DTC Toolkit to find a Wiki-friendly guide.
GATE
Simulations of Preclinical and Clinical Scans in Emission Tomography, Transmission Tomography and Radiation Therapy
Geant4 is a C++ library, where an application / simulation is built by writing certain C++ classes (geometry, beam, scoring, output, physics), and compiling the binaries from where the simulations are run. Only certain modifications to the simulations can be made with the binaries, such as beam settings, certain physics settings as well as geometry objects pre-defined to be variable.
GATE is an application written for Geant4. It was originally meant for PET and SPECT uses, however it is very flexible so many different kinds of detectors can be designed. To run GATE, only macro files written in the Geant4 scripting language (with some GATE specific commands) are needed to build the geometry, scoring, physics and beam. The output is also defined in the macro files, either to ASCII files or to ROOT files.
In each simulation, the user has to:
- define the scanner geometry
- set up the physics processes
- initialize the simulation
- set up the detector model
- define the source(s)
- specify the data output format
- start the acquisition
Introduction to GATE macros
Gate, just as GEANT4, is a program in which the user interface is based on scripts. To perform actions, the user must either enter commands in interactive mode, or build up macro files containing an ordered collection of commands.
Each command performs a particular function, and may require one or more parameters. The Gate commands are organized following a tree structure, with respect to the function they represent. For example, all geometry-control commands start with geometry, and they will all be found under the /geometry/ branch of the tree structure.
When Gate is run, the Idle> prompt appears. At this stage the command interpreter is active; i.e. all the Gate commands entered will be interpreted and processed on-line. All functions in Gate can be accessed to using command lines. The geometry of the system, the description of the radioactive source(s), the physical interactions considered, etc., can be parameterized using command lines, which are translated to the Gate kernel by the command interpreter. In this way, the simulation is defined one step at a time, and the actual construction of the geometry and definition of the simulation can be seen on-line. If the effect is not as expected, the user can decide to re-adjust the desired parameter by re-entering the appropriate command on-line. Although entering commands step by step can be useful when the user is experimenting with the software or when he/she is not sure how to construct the geometry, there remains a need for storing the set of commands that led to a successful simulation.
Macros are ASCII files (with '.mac' extension) in which each line contains a command or a comment. Commands are GEANT4 or Gate scripted commands; comments start with the character ' #'. Macros can be executed from within the command interpreter in Gate, or by passing it as a command-line parameter to Gate, or by calling it from another macro. A macro or set of macros must include all commands describing the different components of a simulation in the right order. Usually these components are visualization, definitions of volumes (geometry), systems, digitizer, physics, initialization, source, output and start. These steps are described in the next sections. A single simulation may be split into several macros, for instance one for the geometry, one for the physics, etc. Usually, there is a master macro which calls the more specific macros. Splitting macros allows the user to re-use one or more of these macros in several other simulations, and/or to organize the set of all commands. To execute a macro (mymacro.mac in this example) from the Linux prompt, just type :
Gate mymacro.mac
To execute a macro from inside the Gate environment, type after the "Idle>" prompt:
Idle>/control/execute mymacro.mac
And finally, to execute a macro from inside another macro, simply write in the master macro:
/control/execute mymacro.mac
Setting up a simple simulation geometry in GATE using a pencil beam and a water phantom
Visualization
First we may want to set up a visualization engine to see what's going on. This is optional, and runs in batch mode should not be visualized! Here we use the opengl visualizer OGLX, but different kinds of visualization engines are discussed in the GATE Wiki [[1]]
/vis/open/OGLX /vis/viewer/reset /vis/viewer/set/viewpointThetaPhi 60 60 /vis/viewer/zoom 1 /vis/viewer/set/style surface /vis/drawVolume /tracking/storeTrajectory 1 /vis/scene/endOfEventAction accumulate /vis/viewer/update
Most of these commands are self explainatory. By using the storeTrajectory command, all particles are displayed together with the geometry.
Materials database
The default material assigned to a new volume is Air. The list of available materials is defined in the GateMaterials.db file. It's included in the Gate folder, and should be copied to the active directory. It is easy to add new materials to the file, just have a look at the file.
/gate/geometry/setMaterialDatabase MyMaterialDatabase.db
Geometry
Apart from specialized geometries such as PET, SPECT, CT, the general geometry is called as scanner. It must be placed within the world volume, and all parts of the detector (to be scored) be placed within the scanner volume.
To construct a simple water phantom geometry of 30x30x30 cm, use the following commands:
/gate/world/geometry/setXLength 1000. cm /gate/world/geometry/setYLength 1000. cm /gate/world/geometry/setZLength 1000. cm
So we've defined a world geometry of 1 m3. It must be larger than all its daughter volumes. Let's put the scanner volume inside the world volume. Since it's not already defined (the world volume was), we must insert a box object (with parameters XLength, YLength, ZLength as the side measurements of the box):
/gate/world/daughters/name scanner /gate/world/daughters/insert box /gate/scanner/geometry/setXLength 100. cm /gate/scanner/geometry/setYLength 100. cm /gate/scanner/geometry/setZLength 100. cm /gate/scanner/vis/forceWireframe
Inside this scanner volume (the default material is Air), let's finally put the water phantom (to start at [math]\displaystyle{ z=0 }[/math]):
/gate/scanner/daughters/name phantom /gate/scanner/daughters/insert box /gate/phantom/geometry/setXLength 30. cm /gate/phantom/geometry/setYLength 30. cm /gate/phantom/geometry/setZLength 30. cm /gate/phantom/placement/setTranslation 0 0 -35. cm # - 100/2 + 30/2 /gate/phantom/setMaterial Water /gate/phantom/vis/forceWireframe
Sensitive Detectors
The scoring system in Geant4/GATE is based around Sensitive Detectors (SD). If a volume is a daughter volume (or granddaughter, ...), it may be assigned as a SD. This process is super simple in GATE:
/gate/phantom/attachCrystalSD
Physics
There are many physics lists to choose from in Geant4/GATE. For proton therapy and detector simulations, I most often use a combination of a low-energy-friendly hadronic list and the variable-steplength (for Bragg Peak accuracy) electromagnetic list. From the Geant4 reference physics webpage [[2]]:
- QGSP: QGSP is the basic physics list applying the quark gluon string model for high energy interactions of protons, neutrons, pions, and Kaons and nuclei. The high energy interaction creates an exited nucleus, which is passed to the precompound model modeling the nuclear de-excitation.
- QGSP_BIC: Like QGSP, but using Geant4 Binary cascade for primary protons and neutrons with energies below ~10GeV, thus replacing the use of the LEP model for protons and neutrons In comparison to teh LEP model, Binary cascade better describes production of secondary particles produced in interactions of protons and neutrons with nuclei.
- emstandard_opt3 designed for any applications required higher accuracy of electrons, hadrons and ion tracking without magnetic field. It is used in extended electromagnetic examples and in the QGSP_BIC_EMY reference Physics List. The corresponding physics
The physics list to use all of these is called QGSP_BIC_EMY. It is loaded with the command
/gate/physics/addPhysicsList QGSP_BIC_EMY
In addition, in order to accurately represent the water in the water phantom, we define the current recommended value for the mean ionization potential for water, which is [math]\displaystyle{ 75\ \mathrm{eV} }[/math]. This can be performed for all materials, and it will override Bragg's additivity rule.
/gate/geometry/setIonisationPotential Water 75 eV
Initialization
After the geometry and physics has been set, initialize the run!
/gate/run/initialize
Proton beam
/gate/source/addSource PBS PencilBeam /gate/source/PBS/setParticleType proton /gate/source/PBS/setEnergy 188.0 MeV /gate/source/PBS/setSigmaEnergy 1.0 MeV /gate/source/PBS/setPosition 0 0 -10. mm /gate/source/PBS/setSigmaX 2 mm /gate/source/PBS/setSigmaY 4 mm /gate/source/PBS/setSigmaTheta 3.3 mrad /gate/source/PBS/setSigmaPhi 3.8 mrad /gate/source/PBS/setEllipseXThetaEmittance 15 mm*mrad /gate/source/PBS/setEllipseXThetaRotationNorm negative /gate/source/PBS/setEllipseYPhiEmittance 20 mm*mrad /gate/source/PBS/setEllipseYPhiRotationNorm negative /gate/application/setTotalNumberOfPrimaries 5000
It is tricky to use this beam since all parameters need to match, so an alternative is to use a uniform General Particle Source:
/gate/source/addSource uniformBeam gps /gate/source/uniformBeam/gps/particle proton /gate/source/uniformBeam/gps/ene/type Gauss /gate/source/uniformBeam/gps/ene/mono 188 MeV /gate/source/uniformBeam/gps/ene/sigma 1 MeV /gate/source/uniformBeam/gps/type Plane /gate/source/uniformBeam/gps/shape Square /gate/source/uniformBeam/gps/direction 0 0 1 /gate/source/uniformBeam/gps/halfx 0 mm /gate/source/uniformBeam/gps/halfy 0 mm /gate/source/uniformBeam/gps/centre 0 0 -1 cm /gate/application/setTotalNumberOfPrimaries 5000
Output
For this tutorial, we will use the ROOT output.
/gate/output/root/enable /gate/output/root/setFileName gate_simulation
Running the simulation
To finalize the macro file, start the randomization engine and run!
/gate/random/setEngineName MersenneTwister /gate/random/setEngineSeed auto /gate/application/start
Running short simulations
To run a simulation, create a macro file with the lines as descibed above, and run it with
$ Gate waterphantom.mac
The terminal output describes the geometry, physics, etc.
It is also possible to use aliases in the macro file. For example, to simplify the energy selection, substitute with the line
/gate/source/PBS/setEnergy {energy} MeV
and run the macro with
$ Gate -a '[energy,175]' waterphantom.mac
Multiple aliases can be stacked:
$ Gate -a '[energy,175] [phantomsize,45]' waterphantom.mac
if you have defined multiple alises in the macro file. It is sadly not possible to do calculations in the macro language, so you have to do that through bash (newvalue=`echo "$oldvalue/2" | bc`
).
Examination of the GATE output files
The ROOT output file(s) from the simulation can be opened several ways:
- By using the built-in
TBrowser
to look at scoring variable distributions - By using loading the ROOT Tree into a C++ program and looping over events (interactions)
Using the built-in TBrowser
The hierarchy for the files are shown in the image below:
In Gate, the TTree is called Hits, and the leaves are named after the different variables that are automatically scored:
PDGEncoding - The Particle ID trackID - Track number following a mother particle parentID - The parent track's event ID. 0 if the current particle is a beam particle time - Time in simulation (for ToF in PET, etc.) edep - Deposited energy in this event / interaction stepLength - The length of the current step posX - Global X position of event posY - Global Y position of event posZ - Global Z position of event localPosX - Local (in mother volume) X position of event localPosY - Local (in mother volume) Y position of event localPosZ - Local (in mother volume) Z position of event baseID - ID of mother volume scanner, == 0 if only one scanner defined level1ID - ID of 1st level of volume hierarchy level2ID - ID of 2nd level of volume hierarchy level3ID - ID of 3rd level of volume hierarchy level4ID - ID of 4th level of volume hierarchy sourcePosX - Global X position of source particle sourcePosY - Global Y position of source particle sourcePosZ - Global X position of source particle eventID - History number (important!!) volumeID - ID of current volume (useful to isolate particles in a specific part of a fully scored volume) processName - A string containing the name of the interaction type: - hIoni: Ionization by hadron - Transportation: No special interactions (usually from step limiter) - eIoni: Ionization by electron - ProtonInelastic: Inelastic nuclear interaction of proton - compt: Compton scattering - ionIoni: Ionization by ion - msc: Multiple Coulomb Scattering process - hadElastic: Elastic hadron / proton scattering
An example of the distribution of eventID (in histogram form, this is the number of interactions per particle (if bin size = 1))
$ root ROOT [0] new TBrowser
Or for the Z distribution (see the Bragg Peak)
Opening the files in C++
It is quite simple to open the generated ROOT files in a C++ program.
In openROOTFile.C
:
#include <TTree.h> #include <TFile.h> using namespace std; void Run() { TFile *f = new TFile("gate_simulation.root"); TTree *tree = (TTree*) f->Get("Hits"); // The TTree in the GATE file is called Hits // Declare the variables (leafs) to be readout Float_t x,y,z,edep; Int_t eventID, parentID; // Make a connection between the declared variables and the leafs tree->SetBranchAddress("posX", &x); tree->SetBranchAddress("posY", &y); tree->SetBranchAddress("posZ", &z); tree->SetBranchAddress("edep", &edep); tree->SetBranchAddress("eventID", &eventID); tree->SetBranchAddress("parentID", &parentID); // Loop over all the entries in the tree for (Int_t i=0, i < tree->GetEntries(); ++i) { tree->GetEntry(i); if (eventID > 2) break; // To limit the output! if (parentID != 0) continue; // Only show results from primary particles printf("Primary particle with event ID %d has an interaction with %.2f MeV energy loss at (x,y,z) = (%.2f, %.2f, %.2f).\n", eventID, edep, x, y, z); } delete f; }
Then you can run the program with
$ root ROOT [0] .L openROOTFile.C+ // The + tells ROOT to compile the code ROOT [1] Run();
Please note that it is also possible to make a complete class to read out the root files using ROOT's MakeClass
function. See [[3]].
Test case: Finding the range and straggling of a proton beam
#include <TTree.h> #include <TH1F.h> #include <TFile.h> using namespace std; void Run() { TFile * f = new TFile("gate_simulation.root"); TTree * tree = (TTree*) f->Get("Hits"); // The TTree in the GATE file is called Hits TH1F * rangeHistogram = new TH1F("rangeHistogram", "Stopping position for protons"; 800, 0, 400); // Histogram 1D with Float values Float_t z; Int_t eventID, parentID;¨ Int_t lastEventID = -1; Float_t lastZ = -1; tree->SetBranchAddress("posZ", &z); tree->SetBranchAddress("eventID", &eventID); tree->SetBranchAddress("parentID", &parentID); for (Int_t i=0, i < tree->GetEntries(); ++i) { tree->GetEntry(i); if (parentID != 0) continue; // Check if this is the first event of a primary particle if (eventID != lastEventID && lastEventID >= 0) { rangeHistogram->Fill(lastZ); } // Store the current variables lastZ = z; lastEventID = eventID; } rangeHistogram->Draw(); // Make a Gaussian fit to the range TF1 * fit = new TF1("fit", "gaus"); rangeHistogram->Fit("fit", "", 350, 400); // Most probable values for fit is in this range, ROOT is quite sensitive to Gaussians occupying only a small part of the histogram, so give narrow fit range printf("The range of the proton beam is %.3f +- %.3f mm.\n", fit->GetParameter(1), fit->GetParameter(2)); }
This time, the program will yield the following output (from a 250 MeV beam):
The range of the proton beam is 378.225 mm +- 3.791 mm
With the following histogram (I've added some color and a SetOptFit to the legend)
Review of the analysis code by Helge Pettersen
Overview:
- Generating the GATE simulation files
- Perfoming GATE simulations
- Interlude - Tuning the analysis for the wanted geometry.
- Making range-energy tables, finding the straggling, etc.
- Tracking analysis: This can be done both simplified and full
- Simplified: No double-modelling of the pixel diffusion process (use MC provded energy loss), no track reconstruction (use eventID tag to connect tracks from same primary).
- The 3D reconstruction of phantoms using tracker planes has not yet been implemented
The analysis toolchain has the following components:
GATE simulations
Geometry scheme
The simplified simulation geometry for the future DTC simulations has been proposed as:
It is partly based on the ALPIDE design, and the FoCal design. The GATE geometry corresponding to this scheme is based on the following hierarchy:
World -> Scanner1 -> Layer -> Module + Absorber + Air gap Module = Active sensor + Passive sensor + Glue + PCB + Glue -> Scanner2 -> [Layer] * Number Of Layers
The idea is that Scanner1 represents the first layer (where e.g. there is no absorber, only air), and that Scanner2 represents all the following (similar) layers which are repeated.
Generating the macro files
To generate the geometry files to run in Gate, a Python script is supplied. It is located within the gate/python subfolder.
[gate/python] $ python gate/python/makeGeometryDTC.py
Choose the wanted characteristics of the detector, and use write files in order to create the geometry file Module.mac, which is automatically included in Main.mac. Note that the option "Use water degrader phantom" should be checked (as is the default behavior)!
Creating the full simulations files for a range-energy look-up-table
In this step, 5000-10000 particles are usually sufficient in order to get accurate results. To loop through different energy degrader thicknesses, run the script runDegraderFull.sh:
[gate/python] $ sh runDegraderFull.sh <absorber thickness> <degraderthickness from> <degraderthickness stepsize> <degraderthickness to>
The brackets indicate the folder in the Github repository to run the code from.
For example, with a 3 mm degrader, and simulating a 250 MeV beam passing through a phantom of 50, 55, 60, 65 and 70 mm water:
[gate/python] $ sh runDegraderFull.sh 3 50 5 70
This is a parallel process, so don't do too much together. I've found that on my 4 core i5, 100 parallel simulations are OK (of course they only get a few % CPU each), but with >200 the virtual machine stops working... So turn on overnight, but know your limits!
Creating the chip-readout simulations files for resolution calculation
In this step a higher number of particles is desired. I usually use 25000 since we need O(100) simulations. A sub 1-mm step size will really tell us if we manage to detect such small changes in a beam energy.
And loop through the different absorber thicknesses:
[gate/python] $ sh runDegrader.sh <absorber thickness> <degraderthickness from> <degraderthickness stepsize> <degraderthickness to>
Creating the basis for range-energy calculations
The range-energy look-up-table
Now we have ROOT output files from Gate, all degraded differently through a varying water phantom and therefore stopping at different places in the DTC. We want to follow all the tracks to see where they end, and make a histogram over their stopping positions. This is of course performed from a looped script, but to give a small recipe:
- Retrieve the first interaction of the first particle. Note its event ID (history number) and edep (energy loss for that particular interaction)
- Repeat until the particle is outside the phantom. This can be found from the volume ID or the z position (the first interaction with {math|z>0}). Sum all the found edep values, and this is the energy loss inside the phantom. Now we have the "initial" energy of the proton before it hits the DTC
- Follow the particle, noting its z position. When the event ID changes, the next particle is followed, and save the last z position of where the proton stopped in a histogram
- Do a Gaussian fit of the histogram after all the particles have been followed. The mean value is the range of the beam with that particular "initial" energy. The spread is the range straggling. Note that the range straggling is more or less constant, but the contributions to the range straggling from the phantom and DTC, respectively, are varying linearly.
This recipe has been implemented in DTCToolkit/Scripts/findRange.C
. Test run the code on a few of the cases (smallest and biggest phantom size ++) to see that
- The correct start- and end points of the histogram looks sane. If not, this can be corrected for by looking how
xfrom
andxto
is calculated and playing with the calculation. - The mean value and straggling is calculated correctly
- The energy loss is calculated correctly
You can run findRange.C
in root by compiling and giving it three arguments; Energy of the protons, absorber thickness, and the degrader thickness you wish to inspect.
[DTCToolkit/Scripts] $ root ROOT [1] .L findRange.C+ // void findRange(Int_t energy, Int_t absorberThickness, Int_t degraderThickness) ROOT [2] findRange f(250, 3, 50); f.Run();
The output should look like this: Correctly places Gaussian fits is a good sign.
If you're happy with this, then a new script will run findRange.C
on all the different ROOT files generated earlier.
[DTCToolkit/Scripts] $ root ROOT [1] .L findManyRangesDegrader.C // void findManyRanges(Int_t degraderFrom, Int_t degraderIncrement, Int_t degraderTo, Int_t absorberThicknessMmFrom, Int_t absorberThicknessMmIncrement, Int_t absorberThicknessMmTo) ROOT [2] findManyRanges(50, 5, 70, 3, 1, 3)
This is a serial process, so don't worry about your CPU.
The output is stored in DTCToolkit/Output/findManyRangesDegrader.csv
.
It is a good idea to look through this file, to check that the values are not very jumpy (Gaussian fits gone wrong).
We need the initial energy and range in ascending order. The findManyRangesDegrader.csv files contains more rows such as initial energy straggling and range straggling for other calcualations. This is sadly a bit tricky, but do (assuming a 3 mm absorber geometry):
[DTCToolkit] $ cat OutputFiles/findManyRangesDegrader.csv | awk '{print ($6 " " $3)}' | sort -n > Data/Ranges/3mm_Al.csv
NB: If there are many different absorber geometries in findManyRangesDegrader, either copy the interesting ones or use | grep " X " |
to only keep X mm geometry
When this is performed, the range-energy table for that particular geometry has been created, and is ready to use in the analysis. Note that since the calculation is based on cubic spline interpolations, it cannot extrapolate -- so have a larger span in the full Monte Carlo simulation data than with the chip readout. For more information about that process, see this document: File:Comparison of different calculation methods of proton ranges.pdf
Range straggling parameterization and [math]\displaystyle{ R_0 = \alpha E^p }[/math]
It is important to know the amount of range straggling in the detector, and the amount of energy straggling after the degrader. In addition, to calculate the parameters [math]\displaystyle{ \alpha, p }[/math] from the somewhat inaccurate Bragg-Kleeman equation [math]\displaystyle{ R_0 = \alpha E ^ p }[/math], in order to correctly model the "depth-dose curve" [math]\displaystyle{ dE / dz = p^{-1} \alpha^{-1/p} (R_0 - z)^{1/p-1} }[/math]. This is done by fitting the Bragg-Kleeman equation to the range-energy look up tables found by using DTCToolkit/Scripts/findManyRangesDegrader.C
.
To find all this, run the script DTCToolkit/Scripts/findAPAndStraggling.C
. This script will loop through all available data lines in the DTCToolkit/OutputFiles/findManyRangesDegrader.csv
file that has the correct absorber thickness, so you need to clean the file first (or just delete it before running findManyRangesDegrader.C
).
[DTCToolkit/Scripts] $ root ROOT [0] .L findAPAndStraggling.C+ // void findAPAndStraggling(int absorberthickness) ROOT [1] findAPAndStraggling(3)
The output from this function should be something like this:
In addition, the following parameters should be extracted:
Bragg-Kleeman parameters: R = 0.011626 E ^ 1.743151 Straggling = 1.8568 + 0.000856 R
Configuring the DTC Toolkit to run with correct geometry
The values from findManyRanges.C
should already be in DTCToolkit/Data/Ranges/3mm_Al.csv
(or the corresponding material / thickness). Check that the file is correctly loaded in the file DTCToolkit/GlobalConstants/MaterialConstants.C
. The values from findAPAndStraggling.C
are put into the same file DTCToolkit/GlobalConstants/MaterialConstants.C
:
81 void createSplines() { ... 107 else if (kAbsorbatorThickness = 3) { 108 in.open("Data/Ranges/3mm_Al.csv"); 109 } ... 192 else if (kAbsorbatorThickness = 3) { 193 alpha_aluminum = 0.011626; 194 p_aluminum = 1.743151; 195 straggling_a = 1.8568; 196 straggling_b = 0.000856; 197 }
Or in the corresponding material (alpha_pmma, alpha_carbon, etc.) and absorbatorthickness lines.
And in the file DTCToolkit/Scripts/makePlots.C
, put the \alpha, p parameters.
144 else if (absorberThickness == 3) { 145 a_dtc = 0.011626; 146 p_dtc = 1.743151; 147 }
Then, look in the file DTCToolkit/GlobalConstants/Constants.h
and check that the correct absorber thickness values etc. are set:
... 39 Bool_t useDegrader = true; ... 52 const Float_t kAbsorberThickness = 3; ... 59 Int_t kEventsPerRun = 100000; ... 66 const Int_t kMaterial = kAluminum;
Since we don't use tracking but only MC truth in the optimization, the number kEventsPerRun ([math]\displaystyle{ n_p }[/math] in the NIMA article) should be higher than the number of primaries per energy.
Running the DTC Toolkit
As mentioned, the analysis toolchain has the following components:
The following section will detail how to perform these separate steps. A quick review of the classes available:
Hit
: A (int x,int y,int layer, float edep) object from a pixel hit. edep information only from MCHits
: ATClonesArray
collection of Hit objectsCluster
: A (float x, float y, int layer, float clustersize) object from a cluster ofHit
s The (x,y) position is the mean position of all involved hits.Clusters
: ATClonesArray
collection ofCluster
objects.Track
: ATClonesArray
collection ofCluster
objects... But only one per layer, and is connected through a physical proton track. Many helpful member functions to calculate track properties.Tracks
: ATClonesArray
collection ofTrack
objects.Layer
: The contents of a single detector layer. Is stored as aTH2F
histogram, and has aLayer::findHits
function to find hits, as well as the cluster diffusion modelLayer::diffuseLayer
. It is controlled from aCalorimeterFrame
object.CalorimeterFrame
: The collection of allLayer
s in the detector.DataInterface
: The class to talk to DTC data, either through semi-Hit
objects as retrieved from Utrecht from the Groningen beam test, or from ROOT files as generated in Gate.
Data readout: MC, MC + truth, experimental
In the class DataInterface
there are several functions to read data in ROOT format.
int getMCFrame(int runNumber, CalorimeterFrame *calorimeterFrameToFill, [..]) <- MC to 2D hit histograms void getMCClusters(int runNumber, Clusters *clustersToFill); <-- MC directly to clusters w/edep and eventID void getDataFrame(int runNumber, CalorimeterFrame *calorimeterFrameToFill, int energy); <- experimental data to 2D hit histograms
To e.g. obtain the experimental data, use
DataInterface *di = new DataInterface(); CalorimeterFrame *cf = new CalorimeterFrame(); for (int i=0; i<numberOfRuns; i++) { // One run is "readout + track reconstruction di->getDataFrame(i, cf, energy); // From here the object cf will contain one 2D hit histogram for each of the layers // The number of events to readout in one run: kEventsPerRun (in GlobalConstants/Constants.h) }
Examples of the usage of these functions are located in DTCToolkit/HelperFunctions/getTracks.C
.
Please note the phenomenological difference between experimental data and MC:
- Exp. data has some noise, represented as "hot" pixels and 1-pixel clusters
- Exp. data has diffused, spread-out, clusters from physics processes
- Monte Carlo data has no such noise, and proton hits are represented as 1-pixel clusters (with edep information)
Pixel diffusion modelling (MC only)
To model the pixel diffusion process, i.e. the the diffusion of the electron-hole pair charges generated from the proton track towards nearby pixels, an empirical model has been implemented. It is described in the NIMA article [[4]], and also in the source code in DTCToolkit/Classes/Layer/Layer.C::diffuseLayer
.
To perform this operation on a filled CalorimeterFrame *cf
, use
TRandom3 *gRandom = new TRandom3(0); // use #import <TRandom3.h> cf->diffuseFrame(gRandom);
Inverse pixel diffusion calculation (MC and exp. data)
This process has been inversed in a Python script, and performed with a large number of input cluster sizes. The result is a parameterization between the proton's energy loss in a layer, and the number of activated pixels:
Cluster identification
Cluster identification is the process to find all connected hits (activated pixels) from a single proton in a single layer. It can be done by several algorithms, simple looped neighboring, DBSCAN, ... The process is such:
- All hits are found from the diffused 2D histograms and stored as
Hit
objects with [math]\displaystyle{ (x,y,layer) }[/math] in a TClonesArray list. - This list is indexed by layer number (a new list with the index the first Hit in each layer) to optimize any search
- The cluster finding algorithm is applied. For every Hit, the Hit list is looped through to find any connected hits. The search is optimized by use of another index list on the vertical position of the Hits. All connected hits (vertical, horizontal and diagonal) are collected in a single Cluster object with [math]\displaystyle{ (x,y,layer,cluster size) }[/math], where the cluster size is the number of its connected pixels.
This task is simply performed on a diffused CalorimeterFrame *cf
:
Hits *hits = cf->findHits(); Clusters *clusters = hits->findClustersFromHits();
Proton track reconstruction
The process of track reconstruction is described fully in [[5]].
From a collection of cluster objects, Clusters * clusters
, use the following code to get a collection of the Track objects connecting them across the layers.
Tracks * tracks = clusters->findCalorimeterTracks();
Some optimization schemes can be applied to the tracks in order to increase their accuracy:
tracks->extrapolateToLayer0(); // If a track was found starting from the second layer, we want to know the extrapolated vector in the first layer tracks->splitSharedClusters(); // If two tracks meet at the same position in a layer, and they share a single cluster, split the cluster into two and give each part to each of the tracks tracks->removeTracksLeavingDetector(); // If a track exits laterally from the detector before coming to a stop, remove it tracks->removeTracksEndingInBadChannnels(); // ONLY EXP DATA: Use a mask containing all the bad chips to see if a track ends in there. Remove it if it does.
Individual tracks: Energy loss fitting
To obtain the most likely residual range / stopping range from a Track object, use
track->doRangeFit(); float residualRange = track->getFitParameterRange();
What happens here is that a TGraph with the ranges and in-layer energy losses of all the Cluster objects is constructed. A differentiated Bragg Curve is fitted to this TGraph:
[math]\displaystyle{ f(z) = p^{-1} \alpha^{-1/p} (R_0 - z)^{1/p-1} }[/math]
With [math]\displaystyle{ p,\alpha }[/math] being the parameters found during the full-scoring MC simulations. The value [math]\displaystyle{ R_0 }[/math], or track::getFitParameterRange
is stored.
(3D reconstruction / MLP estimation)
Residual range calculation
Geometry optimization: How does the DTC Toolkit calculate resolution?
The resolution in this case is defined as the width of the final range histogram for all protons. The goal is to match the range straggling which manifests itself in the Gaussian distribution of the range of all protons in the DTC, from the full Monte Carlo simulations:
To characterize the resolution, a realistic analysis is performed. Instead of scoring the complete detector volume, including the massive energy absorbers, only the sensor chips placed at intervals ([math]\displaystyle{ \Delta z = 0.375\ \textrm{mm} + d_{\textrm{absorber}} }[/math]) are scored. Tracks are compiled by using the eventID tag from GATE, so that the track reconstruction efficiency is 100%. Each track is then put in a depth / edep graph, and a Bragg curve is fitted on the data:
The distribution of all fitted ranges (simple to calculate from fitted energy) should match the distribution above - with a perfect system. All degradations during analysis, sampling error, sparse sampling, mis-fitting etc. will ensure that the peak is broadened.
PS: Please forgive me the fact that the first figure is given in projected range, the second figure is given in initial energy and the third figure is given in projected water equivalent range...... They are converted losslessly since LUTs are used.
Finding the resolution
To find this resolution, or degradation in the straggling width, for a single energy, run the DTC toolkit analysis.
[DTCToolkit] $ root Load.C // drawBraggPeakGraphFit(Int_t Runs, Int_t dataType = kMC, Bool_t recreate = 0, Float_t energy = 188, Float_t degraderThickness = 0) ROOT [0] drawBraggPeakGraphFit(1, 0, 1, 250, 34)
This is a serial process, so don't worry about your CPU when analysing all ROOT files in one go. With the result
The following parameters are then stored in DTCToolkit/OutputFiles/results_makebraggpeakfit.csv
:
Absorber thickness | Degrader thickness | Nominal WEPL range | Calculated WEPL range | Nominal WEPL straggling | Calculated WEPL straggling |
3 (mm) | 34 (mm) | 345 (mm WEPL) | 345.382 (mm WEPL) | 2.9 (mm WEPL) | 6.78 (mm WEPL) |
To perform the analysis on all different degrader thicknesses, use the script DTCToolkit/makeFitResultPlotsDegrader.sh
(arguments: degrader from, degrader step and degrader to):
[DTCToolkit] $ sh makeFitResultsPlotsDegrader.sh 1 1 380
This may take a few minutes... When it's finished, it's important to look through the file results_makebraggpeakfit.csv to identify all problem energies, as this is a more complicated analysis than the range finder above. If any is identified, run the drawBraggPeakGraphFit at that specific degrader thickness to see where the problems are.
Displaying the results
If there are no problems, use the script DTCToolkit/Scripts/makePlots.C
to plot the contents of the file DTCToolkit/OutputFiles/results_makebraggpeakfit.csv
:
[DTCToolkit/Scripts/optimization] $ root plotRangesAndStraggling.C
The output is a map of the accuracy of the range determination, and a comparison between the range resolution (#sigma of the range determination) and its lower limit, the range straggling.
"Hands on" to the analysis code
A review of the different modules in the code
The Digital Tracking Calorimeter Toolkit is located at Helge's github (but should be moved to the Gitlab when ready).
To clone the project, run
git clone https://github.com/HelgeEgil/focal
in a new folder to contain the project. The folder structure will be
DTCToolkit/ <- the reconstruction and analysis code DTCToolkit/Analysis <- User programs for running the code DTCToolkit/Classes <- All the classes needed for the project DTCToolkit/Data <- Data files: Range-energy look up tables, Monte Carlo code, LET data from experiments, the beam data from Groningen, ... DTCToolkit/GlobalConstants <- Constants to adjust how the programs are run. Material parameters, geometry, ... DTCToolkit/HelperFunctions <- Small programs to help running the code. DTCToolkit/OutputFiles <- All output files (csv, jpg, ...) should be put here DTCToolkit/RootFiles <- ROOT specific configuration files. DTCToolkit/Scripts <- Independent scripts for helping the analysis. E.g. to create Range-energy look up tables from Monte Carlo data gate/ <- All Gate-related files gate/python <- The DTC geometry builder projects/ <- Other projects related to WP1
The best way to learn how to use the code is to look at the user programs, e.g. Analysis.C::DrawBraggPeakGraphFit which is the function used to create the Bragg Peak model fits and beam range estimation used in the 2017 NIMA article. From here it is possible to follow what the code does. It is also a good idea to read through what the different classes are and how they interact:
Hit
: A (int x,int y,int layer, float edep) object from a pixel hit. edep information only from MCHits
: ATClonesArray
collection of Hit objectsCluster
: A (float x, float y, int layer, float clustersize) object from a cluster ofHit
s The (x,y) position is the mean position of all involved hits.Clusters
: ATClonesArray
collection ofCluster
objects.Track
: ATClonesArray
collection ofCluster
objects... But only one per layer, and is connected through a physical proton track. Many helpful member functions to calculate track properties.Tracks
: ATClonesArray
collection ofTrack
objects.Layer
: The contents of a single detector layer. Is stored as aTH2F
histogram, and has aLayer::findHits
function to find hits, as well as the cluster diffusion modelLayer::diffuseLayer
. It is controlled from aCalorimeterFrame
object.CalorimeterFrame
: The collection of allLayer
s in the detector.DataInterface
: The class to talk to DTC data, either through semi-Hit
objects as retrieved from Utrecht from the Groningen beam test, or from ROOT files as generated in Gate.
To run the code, do
[DTCToolkit] $ root Load.C
and ROOT will run the script Load.C
which loads all code and starts the interpreter. From here it is possible to directly run scripts as defined in the Analysis.C
file:
ROOT [1] drawBraggPeakGraphFit(...)
DISCLAIMER: Some of the materials have been copied from the GATE v7.2 User's guide: http://wiki.opengatecollaboration.org/index.php/Users_Guide_V7.2