| 1 |
\section{Introduction}
|
| 2 |
|
| 3 |
The purpose of the calibration of the Hadronic Calorimeter systems with
|
| 4 |
physics events is to derive response corrections (RC) and to establish a stable
|
| 5 |
hadronic energy scale. It is intended to improve on the calibration state of
|
| 6 |
the detector established with the available techniques and sources prior to
|
| 7 |
the start of collision data taking.
|
| 8 |
|
| 9 |
Before CMS assembly, a limited number of calorimeter modules were exposed to test beams of
|
| 10 |
pions with known energies to obtain reference calibrations.
|
| 11 |
The energy scale was later propagated to the remaining modules
|
| 12 |
in the assembled detector using Co60 radioactive sources.
|
| 13 |
Details of the test beam analysis and the wiresourcing can be found in
|
| 14 |
%Sect~\ref{S:testbeam}.
|
| 15 |
\cite{testbeam} and \cite{wiresource}, respectively.
|
| 16 |
|
| 17 |
The calibration of the detector was further improved using cosmic muons and splash events.
|
| 18 |
Both methods provided valuable information that allowed us to equalize the detector
|
| 19 |
response in the +/- sides of HB, and derive relative channel-to-channel corrections
|
| 20 |
in HB and HE. Splash events were also used in the identification of the most pronounced
|
| 21 |
"spikes" in HF.
|
| 22 |
|
| 23 |
%One of the deficiencies of the wiresource calibrations is that it does not account for
|
| 24 |
%the non-uniform dead material between the HCAL and ECAL.
|
| 25 |
|
| 26 |
The results with the above mentioned techniques have contributed to
|
| 27 |
the establishment of good reference points for the energy response of the HCAL
|
| 28 |
sub-detectors. However, they do not account for the effect of dead material
|
| 29 |
in front of the calorimeter towers as a function of their location.
|
| 30 |
Therefore, we need to employ additional techniques that can be applied throughout
|
| 31 |
the operation of CMS and account for the conditions applicable to particles produced
|
| 32 |
in collisions.
|
| 33 |
|
| 34 |
|
| 35 |
|
| 36 |
There are two components in the calibration:
|
| 37 |
\begin{itemize}
|
| 38 |
\item{Equalize the response of the detector in $\eta$ and $\phi$
|
| 39 |
(relative corrections)}
|
| 40 |
\item{Set a reproducible global hadronic energy scale
|
| 41 |
(absolute corrections)}
|
| 42 |
\end{itemize}
|
| 43 |
|
| 44 |
The corrections are derived with respect to the ``precalibrated'' conditions.
|
| 45 |
|
| 46 |
Due to the complex structure of the hadronic calorimeter, its large coverage
|
| 47 |
and different overlapping regions with other detector systems used in the calibration
|
| 48 |
procedure, these goals can only
|
| 49 |
be achieved through the use of multiple techniques and data samples.
|
| 50 |
Additional complications come from the non-linearity of the HCAL
|
| 51 |
energy response and the relatively large lateral size of hadronic showers.
|
| 52 |
Due to the nonlinear response of HCAL it is not possible to set an
|
| 53 |
absolute scale that is valid
|
| 54 |
for all energies of incident hadrons. We define the target absolute scale
|
| 55 |
to correspond to $E_{had}/p_{trk}$=1
|
| 56 |
for MIP-like charged hadrons with momentum 50~GeV in the barrel
|
| 57 |
($E_{had}$ measured in a tower cluster as described in Section~\ref{section:hcalIsoTracCalib}).
|
| 58 |
The criteria for this choice is that the energy is in a region where
|
| 59 |
the calorimeter response as a function of energy
|
| 60 |
is slowly changing and it can be set and tested directly.
|
| 61 |
|
| 62 |
In 2008 the HCAL DPG proposed a calibration workflow that includes several
|
| 63 |
techniques that covers the calibration of HB, HE and HF. It was targeted at
|
| 64 |
early data calibrations that can be performed with tens of $pb^{-1}$.
|
| 65 |
The calibration workflow includes the following steps:
|
| 66 |
\begin{itemize}
|
| 67 |
\item{equalize the response in HB, HE, and HF within rings of
|
| 68 |
constant $\eta$ (azimuthal symmetry corrections)}
|
| 69 |
\item{equalize $\eta$ response in HB and part of HE using isolated
|
| 70 |
tracks, obtain absolute energy corrections}
|
| 71 |
\item{equalize $\eta$ response in HE and HF using di-jet events,
|
| 72 |
obtain absolute scale corrections}
|
| 73 |
\end{itemize}
|
| 74 |
|
| 75 |
The calibration steps are not completely independent: the results of each step are used in the
|
| 76 |
subsequent one. A schematic view of the proposed calibration procedure is shown in
|
| 77 |
Figure~\ref{figure:hcalWorkflow}.
|
| 78 |
|
| 79 |
\begin{figure}[!Hhtb]
|
| 80 |
\begin{center}
|
| 81 |
\includegraphics*[width=12cm]{figs/hcalWorkflow08.eps}
|
| 82 |
\caption{Schematic view of the HCAL calibration workflow proposed in CSA08.}
|
| 83 |
\label{figure:hcalWorkflow}
|
| 84 |
\end{center}
|
| 85 |
\end{figure}
|
| 86 |
|
| 87 |
|
| 88 |
This Note provides a description of the techniques and summarizes the results of the
|
| 89 |
feasibility studies for the proposed scheme with MC events.
|
| 90 |
It is restricted to the treatment of HB, HE, and HF.
|
| 91 |
The calibration of HO with collisions data is expected to
|
| 92 |
require much larger samples and will be treated separately. ZDC and Castor calibration with collisions
|
| 93 |
data are in the planning stages and are also excluded form this discussion.
|
| 94 |
|
| 95 |
|
