Version 1 vs 21
Version 1 vs 21
Content Changes
Content Changes
For the first run we are going to simulate simple LEP with the default setup and look at the output.
Create a folder with
mkdir herwig-tutorial
and copy the input file LEP.in that you find under /src into that folder.
Then type the following commands in order to simulate 1000 LEP events:
Herwig read LEP.in
Herwig run LEP.run -N 1000
In the next step have a look at the file LEP.log that displays the first 10 events of that run. Each event is made up of individual steps that reflect the treatment of the event as it passes through the various stages of the generator (hard subprocess, parton shower, hadronization and decays). Try to make sense of the numbers displayed and try to find the individual steps in the event record (the LEP.log file).
Since only looking at numbers is tedious and we cannot really learn something from the .log file we now try to compare the simulation with data.
For that purpose we need to modify the LEP.in file and include the following part
read snippets/Rivet.in
insert /Herwig/Analysis/Rivet:Analyses 0 ALEPH_1996_S3486095
before the line 'saverun LEP EventGenerator'
For the first run, we are going to simulate a LEP event with the default setup and look at the output files.
First, create a folder
mkdir herwig-tutorial
cd herwig-tutorial
and copy the input file LEP.in that you will find under {Herwigpath}/share/Herwig/ or here into that folder.
{F542999}
You can download the input file via
wget https://phab-files.hepforge.org/file/download/d3y555lituggiomcwatj/PHID-FILE-hirg3s3rz7xph4yuaij6/LEP.in
Have a look at the input file with the tool of your choice and try to understand what process is being simulated.
gedit LEP.in
vi LEP.in
less LEP.in
cat LEP.in
emacs LEP.in
Then execute the following commands in order to simulate 10000 LEP events:
Herwig read LEP.in
Herwig run LEP.run -N 10000
In the next step, have a look at the "LEP.log" file that displays the first 10 events of that run. Each event is made up of individual steps that reflect the treatment of the event as it passes through the various stages of the generator (hard subprocess, parton shower, hadronization and decays). Try to make sense of the numbers displayed and try to find the individual steps in the event record (the LEP.log file).
Looking at numbers is tedious. In order to make our life easier we now try to compare the simulation with data from the ALEPH experiment.
For that purpose, we need to modify the LEP.in input file and include the following part
cd /Herwig/Generators
read snippets/Rivet.in
insert /Herwig/Analysis/Rivet:Analyses 0 ALEPH_1996_S3486095
right above the line "saverun LEP EventGenerator".
Now we need to run Herwig again. The steps are the same as above but now we should have created a "LEP.yoda" file. A yoda file is a file created by [[ https://yoda.hepforge.org/ | YODA ]] which is a lightweight common system for MC event generator validation analyses, particularly as the core histogramming system in [[ https://rivet.hepforge.org/ | Rivet ]]. In order to plot this yoda file, we use the following command
rivet-mkhtml LEP.yoda
This creates a folder named "rivet-plots" that collects all the created histograms of the ALEPH analysis. You can display the analysis in your browser by opening the file.
rivet-plots/index.html
Have a look at the created histograms and try to roughly understand what is being measured.
Also, change the name of the **.yoda** file to **LEP-default.yoda** with
mv LEP.yoda LEP-default.yoda
# Switching off the Parton Shower
In the next step, we switch off the Parton Shower and compare the simulation to the one that includes the Parton Shower.
Add the following lines to the input file
cd /Herwig/EventHandlers
set EventHandler:CascadeHandler NULL
right below
set EventGenerator:EventHandler:LuminosityFunction:Energy 91.2
Then, run Herwig again with 10000 Events
Herwig read LEP.in
Herwig run LEP.run -N 10000
and plot the two yoda files together with
rivet-mkhtml LEP-default.yoda LEP.yoda
Now, have a look at the histograms. Why is the mean charged multiplicity larger without a Parton Shower?
Optional: You can also include more [[ https://rivet.hepforge.org/analyses/ | Rivet analyses ]].
For the first run, we are going to simulate simple LEPa LEP event with the default setup and look at the output files.
CFirst, create a folder with
mkdir herwig-tutorial
cd herwig-tutorial
and copy the input file LEP.in that you will find under /src into that folder.
Then type the following commands in order to simulate 1000 LEP events:{Herwigpath}/share/Herwig/ or here into that folder.
{F542999}
Herwig read LEP.inYou can download the input file via
Herwig run LEP.run -N 1000
wget https://phab-files.hepforge.org/file/download/d3y555lituggiomcwatj/PHID-FILE-hirg3s3rz7xph4yuaij6/LEP.in
In the next step have a look at the file LEP.log that displays the first 10 events of that run. Each event is made up of individual steps that reflect the treatment of the event as it passes through the various stages of the generator (hard subprocess, parton shower, hadronization and decays). Try to make sense of the numbers displayed and try to find the individual steps in the event record (the LEP.log file).
Since only looking at numbers is tedious and we cannot really learn something from the .log file we now try to compare the simulation with data.Have a look at the input file with the tool of your choice and try to understand what process is being simulated.
gedit LEP.in
vi LEP.in
less LEP.in
cat LEP.in
emacs LEP.in
For that purpose we need to modify the LEP.in file and include the following partThen execute the following commands in order to simulate 10000 LEP events:
Herwig read LEP.in
Herwig run LEP.run -N 10000
In the next step, have a look at the "LEP.log" file that displays the first 10 events of that run. Each event is made up of individual steps that reflect the treatment of the event as it passes through the various stages of the generator (hard subprocess, parton shower, hadronization and decays). Try to make sense of the numbers displayed and try to find the individual steps in the event record (the LEP.log file).
Looking at numbers is tedious. In order to make our life easier we now try to compare the simulation with data from the ALEPH experiment.
For that purpose, we need to modify the LEP.in input file and include the following part
cd /Herwig/Generators
read snippets/Rivet.in
insert /Herwig/Analysis/Rivet:Analyses 0 ALEPH_1996_S3486095
before the line 'saverun LEP EventGenerator'right above the line "saverun LEP EventGenerator".
Now we need to run Herwig again. The steps are the same as above but now we should have created a "LEP.yoda" file. A yoda file is a file created by [[ https://yoda.hepforge.org/ | YODA ]] which is a lightweight common system for MC event generator validation analyses, particularly as the core histogramming system in [[ https://rivet.hepforge.org/ | Rivet ]]. In order to plot this yoda file, we use the following command
rivet-mkhtml LEP.yoda
This creates a folder named "rivet-plots" that collects all the created histograms of the ALEPH analysis. You can display the analysis in your browser by opening the file.
rivet-plots/index.html
Have a look at the created histograms and try to roughly understand what is being measured.
Also, change the name of the **.yoda** file to **LEP-default.yoda** with
mv LEP.yoda LEP-default.yoda
# Switching off the Parton Shower
In the next step, we switch off the Parton Shower and compare the simulation to the one that includes the Parton Shower.
Add the following lines to the input file
cd /Herwig/EventHandlers
set EventHandler:CascadeHandler NULL
right below
set EventGenerator:EventHandler:LuminosityFunction:Energy 91.2
Then, run Herwig again with 10000 Events
Herwig read LEP.in
Herwig run LEP.run -N 10000
and plot the two yoda files together with
rivet-mkhtml LEP-default.yoda LEP.yoda
Now, have a look at the histograms. Why is the mean charged multiplicity larger without a Parton Shower?
Optional: You can also include more [[ https://rivet.hepforge.org/analyses/ | Rivet analyses ]].