claudioc/OSNote2010/systematics.tex

\section{Acceptance and efficiency systematics}
\label{sec:systematics}

{\bf \color{red} SOME OF THESE STUDIES NEED TO BE UPDATED WITH 38X MC}
This is a search for new physics contributions to 
events with high \met and lots of jet activity.
As seen in Section~\ref{sec:results}, there is no
evidence for a contribution beyond SM expectations.

Strictly speaking it is impossible to talk about 
``acceptance and efficiency systematics'' because these kinds of
systematics only apply to a well defined final state.
Nevertheless, we can make general statements about the 
systematic uncertainties, including quantitative
estimates of the systematic uncertainties associated with
a few specific processes.

The systematic uncertainty on the lepton acceptance consists
of two parts: the trigger efficiency uncertainty and the 
ID and isolation uncertainty.  We discuss these in turn.

The trigger efficiency 
for two leptons of $P_T>10$ GeV, with one lepton of 
$P_T>20$ GeV is very high, except in some corners
of phase space, see Section~\ref{sec:trgeffsum}. 
We estimate the efficiency uncertainty to be a few percent,
mostly in the low $P_T$ region.

\begin{figure}[tbh]
\begin{center}
\includegraphics[width=1.0\linewidth]{eff_35.png}
\includegraphics[width=1.0\linewidth]{isoEff.png}
\caption{\label{fig:effttbar}\protect 
Identification and isolation efficiencies for 
leptons from $t \to W \to \ell$ and 
$t \to W \to \tau \to \ell$ in 
$t\bar{t}$ events.}
\end{center}
\end{figure}


\begin{table}[hbt]
\begin{center}
\caption{\label{tab:tagandprobe} Tag and probe results on $Z \to \ell \ell$
on data and MC.  We quote ID efficiency given isolation and 
the isolation efficiency given ID.}
\begin{tabular}{|l||c|c|}
\hline
                             & Data  T\&P      & MC T\&P    \\  \hline
$\epsilon(id|iso)$ electrons & $0.909\pm0.006$ & 0.926 \\
$\epsilon(iso|id)$ electrons & $0.987\pm0.003$ & 0.985 \\
$\epsilon(id|iso)$ muons     & $0.955\pm0.003$ & 0.953 \\
$\epsilon(iso|id)$ muons     & $0.984\pm0.003$ & 0.981 \\ 
\hline
\end{tabular}
\end{center}
\end{table}


The ID efficiencies in MC are shown in 
Figures~\ref{fig:effttbar}
for the leptons from $t \to W \to \ell$ and $t \to W \to \tau \to \ell$.
Tag and probe studies show that these are correct to about 2\%,
see Table~\ref{tab:tagandprobe}.
Note that the isolation efficiency depends on the jet activity in
the final state.  For example, in MC we find that the
lepton isolation efficiency differs by $\approx 4\%$ 
{\bf per lepton} between $Z$ events and $t\bar{t}$ events\cite{ref:top}.
%\noindent {\bf This figure should be cut off at 100 GeV, and 
%the y-axis should be zero-suppressed}

Another significant source of systematic uncertainty is 
associated with the jet and $\met$ energy scale.  The impact
of this uncertainty is final-state dependent.  Final
states characterized by lots of hadronic activity and \met are 
less sensitive than final states where the \met and SumJetPt
are typically close to the requirement.  To be more quantitative,
we have used the method of Reference~\cite{ref:top} to evaluate
the systematic uncertainties on the acceptance for $t\bar{t}$ 
and two benchmark SUSY points.  The uncertainties are calculated
assuming a 5\% uncertainty to the hadronic energy scale in CMS.

For $t\bar{t}$ we find uncertainties of 8\% (baseline 
selection) and 30\% (signal region D); for LM0 and LM1 we find
14\% and 6\% respectively for signal region D.
Revision:	1.15
Committed:	Thu Dec 2 16:42:37 2010 UTC (14 years, 5 months ago) by benhoob
Content type:	application/x-tex
Branch:	MAIN
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Log Message:	Update with 38X MC results
#	Content
1	\section{Acceptance and efficiency systematics}
2	\label{sec:systematics}
3
4	{\bf \color{red} SOME OF THESE STUDIES NEED TO BE UPDATED WITH 38X MC}
5	This is a search for new physics contributions to
6	events with high \met and lots of jet activity.
7	As seen in Section~\ref{sec:results}, there is no
8	evidence for a contribution beyond SM expectations.
9
10	Strictly speaking it is impossible to talk about
11	``acceptance and efficiency systematics'' because these kinds of
12	systematics only apply to a well defined final state.
13	Nevertheless, we can make general statements about the
14	systematic uncertainties, including quantitative
15	estimates of the systematic uncertainties associated with
16	a few specific processes.
17
18	The systematic uncertainty on the lepton acceptance consists
19	of two parts: the trigger efficiency uncertainty and the
20	ID and isolation uncertainty. We discuss these in turn.
21
22	The trigger efficiency
23	for two leptons of $P_T>10$ GeV, with one lepton of
24	$P_T>20$ GeV is very high, except in some corners
25	of phase space, see Section~\ref{sec:trgeffsum}.
26	We estimate the efficiency uncertainty to be a few percent,
27	mostly in the low $P_T$ region.
28
29	\begin{figure}[tbh]
30	\begin{center}
31	\includegraphics[width=1.0\linewidth]{eff_35.png}
32	\includegraphics[width=1.0\linewidth]{isoEff.png}
33	\caption{\label{fig:effttbar}\protect
34	Identification and isolation efficiencies for
35	leptons from $t \to W \to \ell$ and
36	$t \to W \to \tau \to \ell$ in
37	$t\bar{t}$ events.}
38	\end{center}
39	\end{figure}
40
41
42	\begin{table}[hbt]
43	\begin{center}
44	\caption{\label{tab:tagandprobe} Tag and probe results on $Z \to \ell \ell$
45	on data and MC. We quote ID efficiency given isolation and
46	the isolation efficiency given ID.}
47	\begin{tabular}{\|l\|\|c\|c\|}
48	\hline
49	& Data T\&P & MC T\&P \\ \hline
50	$\epsilon(id\|iso)$ electrons & $0.909\pm0.006$ & 0.926 \\
51	$\epsilon(iso\|id)$ electrons & $0.987\pm0.003$ & 0.985 \\
52	$\epsilon(id\|iso)$ muons & $0.955\pm0.003$ & 0.953 \\
53	$\epsilon(iso\|id)$ muons & $0.984\pm0.003$ & 0.981 \\
54	\hline
55	\end{tabular}
56	\end{center}
57	\end{table}
58
59
60	The ID efficiencies in MC are shown in
61	Figures~\ref{fig:effttbar}
62	for the leptons from $t \to W \to \ell$ and $t \to W \to \tau \to \ell$.
63	Tag and probe studies show that these are correct to about 2\%,
64	see Table~\ref{tab:tagandprobe}.
65	Note that the isolation efficiency depends on the jet activity in
66	the final state. For example, in MC we find that the
67	lepton isolation efficiency differs by $\approx 4\%$
68	{\bf per lepton} between $Z$ events and $t\bar{t}$ events\cite{ref:top}.
69	%\noindent {\bf This figure should be cut off at 100 GeV, and
70	%the y-axis should be zero-suppressed}
71
72	Another significant source of systematic uncertainty is
73	associated with the jet and $\met$ energy scale. The impact
74	of this uncertainty is final-state dependent. Final
75	states characterized by lots of hadronic activity and \met are
76	less sensitive than final states where the \met and SumJetPt
77	are typically close to the requirement. To be more quantitative,
78	we have used the method of Reference~\cite{ref:top} to evaluate
79	the systematic uncertainties on the acceptance for $t\bar{t}$
80	and two benchmark SUSY points. The uncertainties are calculated
81	assuming a 5\% uncertainty to the hadronic energy scale in CMS.
82
83	For $t\bar{t}$ we find uncertainties of 8\% (baseline
84	selection) and 30\% (signal region D); for LM0 and LM1 we find
85	14\% and 6\% respectively for signal region D.