\section{Detector and simulation}
\label{sec:Detector}
The \lhcb detector~\cite{Alves:2008zz,LHCb-DP-2014-002} is a single-arm forward
spectrometer covering the \mbox{pseudorapidity} range $2<\eta <5$,
designed for the study of particles containing \bquark or \cquark
quarks. The detector includes a high-precision tracking system
consisting of a silicon-strip vertex detector surrounding the $pp$
interaction region~\cite{LHCb-DP-2014-001}\verb!*!, a large-area silicon-strip detector located
upstream of a dipole magnet with a bending power of about
$4{\mathrm{\,Tm}}$, and three stations of silicon-strip detectors and straw
drift tubes~\cite{LHCb-DP-2013-003}\verb!*! placed downstream of the magnet.
The tracking system provides a measurement of momentum, \ptot, of charged particles with
a relative uncertainty that varies from 0.5\% at low momentum to 1.0\% at 200\gevc.
The minimum distance of a track to a primary vertex (PV), the impact parameter (IP),
is measured with a resolution of $(15+29/\pt)\mum$,
where \pt is the component of the momentum transverse to the beam, in\,\gevc.
Different types of charged hadrons are distinguished using information
from two ring-imaging Cherenkov detectors~\cite{LHCb-DP-2012-003}\verb!*!.
Photons, electrons and hadrons are identified by a calorimeter system consisting of
scintillating-pad and preshower detectors, an electromagnetic
calorimeter and a hadronic calorimeter. Muons are identified by a
system composed of alternating layers of iron and multiwire
proportional chambers~\cite{LHCb-DP-2012-002}\verb!*!.
The online event selection is performed by a trigger~\cite{LHCb-DP-2012-004}\verb!*!,
which consists of a hardware stage, based on information from the calorimeter and muon
systems, followed by a software stage, which applies a full event
reconstruction.
A more detailed description of the 'full event reconstruction' could be:
\begin{itemize}
\item
The trigger~\cite{LHCb-DP-2012-004}\verb!*! consists of a
hardware stage, based on information from the calorimeter and muon
systems, followed by a software stage, in which all charged particles
with $\pt>500\,(300)\mev$ are reconstructed for 2011\,(2012) data.
For triggers that require neutral particles,
energy deposits in the electromagnetic calorimeter are
analysed to reconstruct \piz and $\gamma$ candidates.
\end{itemize}
The trigger description has to be specific for the analysis in
question. In general, you should not attempt to describe the full
trigger system. Below are a few variations that inspiration can be
taken from. First from a hadronic analysis, and second from an
analysis with muons in the final state. In case you have to look
up specifics of a certain trigger, a detailed description of the trigger
conditions for Run 1 is available in Ref.~\cite{LHCb-PUB-2014-046}.
{\bf Never cite this note in a PAPER or CONF-note.}
\begin{itemize}
\item At the hardware trigger stage, events are required to have a muon with high \pt or a
hadron, photon or electron with high transverse energy in the calorimeters. For hadrons,
the transverse energy threshold is 3.5\gev.
The software trigger requires a two-, three- or four-track
secondary vertex with a significant displacement from any primary
$pp$ interaction vertex. At least one charged particle
must have a transverse momentum $\pt > 1.6\gevc$ and be
inconsistent with originating from a PV.
A multivariate algorithm~\cite{BBDT} is used for
the identification of secondary vertices consistent with the decay
of a \bquark hadron.
%\item The software trigger requires a two-, three- or four-track
% secondary vertex with a large sum of the transverse momentum, \pt, of
% the tracks and a significant displacement from the primary $pp$
% interaction vertices~(PVs). At least one track should have $\pt >
% 1.7\gevc$ and \chisqip with respect to any
% primary interaction greater than 16, where \chisqip is defined as the
% difference in \chisq of a given PV reconstructed with and
% without the considered track.\footnote{If this sentence is used to define \chisqip
% for a composite particle instead of for a single track, replace ``track'' by ``particle'' or ``candidate''}
% A multivariate algorithm~\cite{BBDT} is used for
% the identification of secondary vertices consistent with the decay
% of a \bquark hadron.
\item The $\decay{\Bd}{\Kstarz\mumu}$ signal candidates are first required
to pass the hardware trigger, which selects events containing at least
one muon with transverse momentum $\pt>1.48\gevc$ in the 7\tev data or
$\pt>1.76\gevc$ in the 8\tev data. In the subsequent software
trigger, at least one of the final-state particles is required to
have $\pt>1.7\gevc$ in the 7\tev data or $\pt>1.6\gevc$ in the 8\tev
data, unless the particle is identified as a muon in which case
$\pt>1.0\gevc$ is required. The final-state particles that
satisfy these transverse momentum criteria are also required
to have an impact parameter larger than $100\mum$ with respect
to all PVs in the event. Finally, the tracks of two or more of
the final-state particles are required to form a vertex that is
significantly displaced from the PVs."
% Candidate events are first required to pass the hardware trigger,
% which selects muons with a transverse momentum $\pt>1.48\gevc$
% in the 7\tev data or $\pt>1.76\gevc$ in the 8\tev data.
% In the subsequent software trigger, at least
% one of the final-state particles is required to have both
% $\pt>0.8\gevc$ and impact parameter larger than $100\mum$ with respect to all
% of the primary $pp$ interaction vertices~(PVs) in the
% event. Finally, the tracks of two or more of the final-state
% particles are required to form a vertex that is significantly
% displaced from the PVs.
\end{itemize}
