TIBTIDNotes/TIBTIDIntNote/Introduction.tex

\section{Introduction}
\label{sec:Introduction}

%\section{The Silicon Strip Tracker Layout}
%\label{sec:Layout}

The CMS SST covers the radial range between $20\cm$ and $110\cm$ around the LHC
interaction point. The barrel region ($| z |  < 110\cm$\footnote{A CMS
  coordinate system, used through this note, is defined in such a way
  that $z$ is the coordinate along the LHC beam axis, $y$ is the
  vertical direction and $x$ complete the system; the origin being the
  nominal beam interaction point.}) 
is split into a Tracker Inner Barrel (TIB) made of four detector
layers, and a Tracker Outer Barrel (TOB) made of six detector
layers. The TIB is complemented by three Tracker Inner Disks 
per side (TID), each Disk being in turn composed of three 
Rings. The forward and backward
regions ($120\cm < |z| < 280\cm$) are covered by nine Tracker
End-Cap (TEC) disks per side. 
The two innermost layers of both TIB and TOB as well as rings number one, two and five
of TEC and one and two of TID are instrumented with double-sided
detector modules assemblies able to provide three-dimensional position measurement of the charged
particle hits.
A complete description of the Silicon Tracker layout (Fig.\ref{fig:layout})  
can be found elsewhere~\cite{ref:layout}.\\
\begin{figure}[!htb]
\begin{center}
  \includegraphics[width=0.85\textwidth]{Figs/rz.pdf}
\end{center}
\caption{Longitudinal cross section of one quarter of the CMS SST. 
Thicker (blue) segments indicate double-sided silicon microstrip modules.
The nominal beam interaction point is located in (0,0), dimensions are in mm. 
The pseudorapidity ($\eta$) coverage is also shown.}
\label{fig:layout}       % Give a unique label
\end{figure}

The entire tracker is inserted in a carbon fiber Support Tube which is attached to
the Electromagnetic Calorimeter. The tracker thermal insulation is
guaranteed by a 'Thermal Shield'. The whole tracker region is embedded into the
3.8~Tesla solenoidal magnetic field. 
%Charged particle transverse momentum resolution of about 1.5\% for centrally-produced 
%muon of 100~GeV/$c$ is expected~\cite{ref:ptdr}. \\


%The CMS Tracker Inner Barrel (TIB) and Disks (TID) are in the low radius part of the Silicon Strip Tracker (SST)
%of CMS, of which a full description can be found in
%~\cite{ref:CMS1}\cite{ref:CMS2}.

This note reviews the integration of the substructures in which the TIB
and the TID are split to ease the construction,
i.e. the mounting and the test of all components (modules, electronics
and cables) on 
%the 16 TIB shell support structures and the 18 TID ring
dedicated mechanical support. 
In a second phase, not covered here, these
substructures 
%the shells and the rings 
will be assembled to build the final TIB and TID
detector.

The note is organized as follows: in section~\ref{sec:layout} the TIB
and TID layouts are described; in section~\ref{sec:} an overview of the main
TIB and TID components is given,  with a particular emphasis on the items which are
of particular relevance for the integration activities; in
section~\ref{} and section~\ref{} the integration procedures and the quality control
tests are throughly reviewed; in section~\ref{} the final TIB and TID
are discussed with respect to the radiation environment.
Revision:	1.5
Committed:	Mon Mar 9 15:41:05 2009 UTC (16 years, 1 month ago) by sguazz
Content type:	application/x-tex
Branch:	MAIN
Changes since 1.4:	+47 -78 lines
Log Message:	Text revision, some figures added, some removed
#	User	Rev	Content
1	sguazz	1.1	\section{Introduction}
2			\label{sec:Introduction}
3
4	lino	1.4	%\section{The Silicon Strip Tracker Layout}
5			%\label{sec:Layout}
6
7	sguazz	1.5	The CMS SST covers the radial range between $20\cm$ and $110\cm$ around the LHC
8			interaction point. The barrel region ($\| z \| < 110\cm$\footnote{A CMS
9			coordinate system, used through this note, is defined in such a way
10			that $z$ is the coordinate along the LHC beam axis, $y$ is the
11			vertical direction and $x$ complete the system; the origin being the
12			nominal beam interaction point.})
13			is split into a Tracker Inner Barrel (TIB) made of four detector
14			layers, and a Tracker Outer Barrel (TOB) made of six detector
15			layers. The TIB is complemented by three Tracker Inner Disks
16			per side (TID), each Disk being in turn composed of three
17			Rings. The forward and backward
18			regions ($120\cm < \|z\| < 280\cm$) are covered by nine Tracker
19			End-Cap (TEC) disks per side.
20	lino	1.4	The two innermost layers of both TIB and TOB as well as rings number one, two and five
21	sguazz	1.5	of TEC and one and two of TID are instrumented with double-sided
22			detector modules assemblies able to provide three-dimensional position measurement of the charged
23			particle hits.
24	lino	1.4	A complete description of the Silicon Tracker layout (Fig.\ref{fig:layout})
25			can be found elsewhere~\cite{ref:layout}.\\
26			\begin{figure}[!htb]
27			\begin{center}
28			\includegraphics[width=0.85\textwidth]{Figs/rz.pdf}
29			\end{center}
30			\caption{Longitudinal cross section of one quarter of the CMS SST.
31			Thicker (blue) segments indicate double-sided silicon microstrip modules.
32			The nominal beam interaction point is located in (0,0), dimensions are in mm.
33			The pseudorapidity ($\eta$) coverage is also shown.}
34			\label{fig:layout} % Give a unique label
35			\end{figure}
36	sguazz	1.5
37	lino	1.4	The entire tracker is inserted in a carbon fiber Support Tube which is attached to
38	sguazz	1.5	the Electromagnetic Calorimeter. The tracker thermal insulation is
39			guaranteed by a 'Thermal Shield'. The whole tracker region is embedded into the
40			3.8~Tesla solenoidal magnetic field.
41			%Charged particle transverse momentum resolution of about 1.5\% for centrally-produced
42			%muon of 100~GeV/$c$ is expected~\cite{ref:ptdr}. \\
43
44
45			%The CMS Tracker Inner Barrel (TIB) and Disks (TID) are in the low radius part of the Silicon Strip Tracker (SST)
46			%of CMS, of which a full description can be found in
47			%~\cite{ref:CMS1}\cite{ref:CMS2}.
48
49			This note reviews the integration of the substructures in which the TIB
50			and the TID are split to ease the construction,
51			i.e. the mounting and the test of all components (modules, electronics
52			and cables) on
53			%the 16 TIB shell support structures and the 18 TID ring
54			dedicated mechanical support.
55			In a second phase, not covered here, these
56			substructures
57			%the shells and the rings
58			will be assembled to build the final TIB and TID
59			detector.
60
61			The note is organized as follows: in section~\ref{sec:layout} the TIB
62			and TID layouts are described; in section~\ref{sec:} an overview of the main
63			TIB and TID components is given, with a particular emphasis on the items which are
64			of particular relevance for the integration activities; in
65			section~\ref{} and section~\ref{} the integration procedures and the quality control
66			tests are throughly reviewed; in section~\ref{} the final TIB and TID
67			are discussed with respect to the radiation environment.