claudioc/OSNote2010/otherBG.tex

\section{Non $t\bar{t}$ Backgrounds}
\label{sec:othBG}

Backgrounds from divector bosons and single top
can be reliably estimated from Monte Carlo.
They are negligible compared to $t\bar{t}$. 
 
Backgrounds from Drell Yan are also expected
to be negligible from MC.  However one always 
worries about the modeling of tails of the \met. 
In the context of other dilepton analyses we 
have developed a data driven method to estimate 
the number of Drell Yan events\cite{ref:dy}.
The method is based on counting the number of
$Z$ candidates passing the full selection, and 
then scaling by the expected ratio of Drell Yan
events outside vs. inside the $Z$ mass 
window.\footnote{A correction based on $e\mu$ events 
is also applied.}  This ratio is called $R_{out/in}$
and is obtained from Monte Carlo.

To estimate the Drell-Yan contribution in the four $ABCD$ 
regions, we count the numbers of $Z \to ee$ and $Z \to \mu\mu$
events falling in each region, we subtract off the number 
of $e\mu$ events with $76 < M(e\mu) < 106$ GeV, and 
we multiply the result by $R_{out/in}$ from Monte Carlo.
The results are summarized in Table~\ref{tab:ABCD-DY}.

\begin{table}[hbt]
\begin{center}
\caption{\label{tab:ABCD-DY} Drell-Yan estimations
in the four 
regions of Figure~\ref{fig:abcdData}.  The yields are
for dileptons with invariant mass consistent with the $Z$.
The factor
$R_{out/in}$ is from MC.  All uncertainties 
are statistical only.  In regions $A$ and $D$ there is no statistics
in the Monte Carlo to calculate $R_{out/in}$.}
\begin{tabular}{|l|c|c|c||c|}
\hline
Region   & $N(ee)+N(\mu\mu)$ & $N(e\mu)$ & $R_{out/in}$ & Estimated DY BG \\
\hline
$A$      &  0                & 0         & ??          & ??$\pm$xx   \\
$B$      &  5                & 1         & 2.5$\pm$1.0 & 9$\pm$xx   \\
$C$      &  0                & 0         & 1.$\pm$1.   & 0$\pm$xx   \\
$D$      &  0                & 0         & ??          & 0$\pm$xx   \\
\hline
\end{tabular}
\end{center}
\end{table}


%When  find no dilepton events with invariant mass
%consistent with the $Z$ in the signal region.
%Using the value of 0.1 for the ratio described above, this 
%means that the Drell Yan background in our signal 
%region is $< 0.23\%$ events at the 90\% confidence level.
%{\color{red} (If we find 1 event this will need to be adjusted)}.

As discussed in Section~\ref{sec:victory}, residual Drell-Yan 
events can have a significant effect on the data driven background
prediction based on $P_T(\ell\ell)$.  This is taken into account,
based on MC expectations, 
by the $K_{\rm{fudge}}$ factor describes in that Section.  
As a cross-check, we use the same Drell Yan background
estimation method described above to estimated the 
number of DY events in the regions $A'B'C'D'$.
The region $A'$ is defined in the same way as the region $A$ 
except that the $\met/\sqrt{\rm SumJetPt}$ requirement is 
replaced by a $P_T(\ell\ell)/\sqrt{\rm SumJetPt}$ requirement.
The regions B', 
C', and D' are defined in a similar way.  The results are
summarized in Table~\ref{tab:ABCD-DYptll}.

\begin{table}[hbt]
\begin{center}
\caption{\label{tab:ABCD-DYptll} Drell-Yan estimations
in the four 
regions $A'B'C'D'$ defined in the text.  The yields are
for dileptons with invariant mass consistent with the $Z$.
The factor
$R_{out/in}$ is from MC.  All uncertainties 
are statistical only.}
\begin{tabular}{|l|c|c|c||c|}
\hline
Region    & $N(ee)+N(\mu\mu)$ & $N(e\mu)$ & $R_{out/in}$ & Estimated DY BG \\
\hline
$A'$      &  3               & 0        & 0.7$\pm$0.3   & 2.1$\pm$xx   \\
$B'$      &  3               & 0        & 2.5$\pm$2.1   & 7.5$\pm$xx   \\
$C'$      &  0               & 0        & 0.1$\pm$0.1   & 0$\pm$xx   \\
$D'$      &  1               & 0        & 0.4$\pm$0.3   & 0.4$\pm$xx   \\
\hline
\end{tabular}
\end{center}
\end{table}


Finally, we can use the ``Fake Rate'' method\cite{ref:FR} 
to predict 
the number of events with one fake lepton. We select
events where one of the leptons passes the full selection and 
the other one fails the full selection but passes the 
``Fakeable Object'' selection of 
Reference~\cite{ref:FR}.\footnote{For electrons we use
the V3 fakeable object definition to avoid complications 
associated with electron ID cuts applied in the trigger.} 
We then weight each event passing the full selection
by FR/(1-FR) where FR is the ``fake rate'' for the 
fakeable object.  {\color{red} The results are...}
Revision:	1.3
Committed:	Sat Nov 6 05:24:16 2010 UTC (14 years, 6 months ago) by claudioc
Content type:	application/x-tex
Branch:	MAIN
Changes since 1.2:	+10 -9 lines
Log Message:	drell yan
#	User	Rev	Content
1	claudioc	1.1	\section{Non $t\bar{t}$ Backgrounds}
2			\label{sec:othBG}
3
4			Backgrounds from divector bosons and single top
5			can be reliably estimated from Monte Carlo.
6			They are negligible compared to $t\bar{t}$.
7
8			Backgrounds from Drell Yan are also expected
9			to be negligible from MC. However one always
10			worries about the modeling of tails of the \met.
11			In the context of other dilepton analyses we
12			have developed a data driven method to estimate
13			the number of Drell Yan events\cite{ref:dy}.
14			The method is based on counting the number of
15			$Z$ candidates passing the full selection, and
16			then scaling by the expected ratio of Drell Yan
17			events outside vs. inside the $Z$ mass
18			window.\footnote{A correction based on $e\mu$ events
19	claudioc	1.2	is also applied.} This ratio is called $R_{out/in}$
20			and is obtained from Monte Carlo.
21
22			To estimate the Drell-Yan contribution in the four $ABCD$
23			regions, we count the numbers of $Z \to ee$ and $Z \to \mu\mu$
24			events falling in each region, we subtract off the number
25			of $e\mu$ events with $76 < M(e\mu) < 106$ GeV, and
26			we multiply the result by $R_{out/in}$ from Monte Carlo.
27			The results are summarized in Table~\ref{tab:ABCD-DY}.
28
29			\begin{table}[hbt]
30			\begin{center}
31			\caption{\label{tab:ABCD-DY} Drell-Yan estimations
32			in the four
33			regions of Figure~\ref{fig:abcdData}. The yields are
34			for dileptons with invariant mass consistent with the $Z$.
35			The factor
36			$R_{out/in}$ is from MC. All uncertainties
37	claudioc	1.3	are statistical only. In regions $A$ and $D$ there is no statistics
38			in the Monte Carlo to calculate $R_{out/in}$.}
39	claudioc	1.2	\begin{tabular}{\|l\|c\|c\|c\|\|c\|}
40			\hline
41			Region & $N(ee)+N(\mu\mu)$ & $N(e\mu)$ & $R_{out/in}$ & Estimated DY BG \\
42			\hline
43	claudioc	1.3	$A$ & 0 & 0 & ?? & ??$\pm$xx \\
44			$B$ & 5 & 1 & 2.5$\pm$1.0 & 9$\pm$xx \\
45			$C$ & 0 & 0 & 1.$\pm$1. & 0$\pm$xx \\
46			$D$ & 0 & 0 & ?? & 0$\pm$xx \\
47	claudioc	1.2	\hline
48			\end{tabular}
49			\end{center}
50			\end{table}
51
52
53
54			%When find no dilepton events with invariant mass
55			%consistent with the $Z$ in the signal region.
56			%Using the value of 0.1 for the ratio described above, this
57			%means that the Drell Yan background in our signal
58			%region is $< 0.23\%$ events at the 90\% confidence level.
59			%{\color{red} (If we find 1 event this will need to be adjusted)}.
60
61			As discussed in Section~\ref{sec:victory}, residual Drell-Yan
62			events can have a significant effect on the data driven background
63			prediction based on $P_T(\ell\ell)$. This is taken into account,
64			based on MC expectations,
65			by the $K_{\rm{fudge}}$ factor describes in that Section.
66			As a cross-check, we use the same Drell Yan background
67			estimation method described above to estimated the
68			number of DY events in the regions $A'B'C'D'$.
69			The region $A'$ is defined in the same way as the region $A$
70			except that the $\met/\sqrt{\rm SumJetPt}$ requirement is
71			replaced by a $P_T(\ell\ell)/\sqrt{\rm SumJetPt}$ requirement.
72			The regions B',
73			C', and D' are defined in a similar way. The results are
74			summarized in Table~\ref{tab:ABCD-DYptll}.
75
76			\begin{table}[hbt]
77			\begin{center}
78			\caption{\label{tab:ABCD-DYptll} Drell-Yan estimations
79			in the four
80			regions $A'B'C'D'$ defined in the text. The yields are
81			for dileptons with invariant mass consistent with the $Z$.
82			The factor
83			$R_{out/in}$ is from MC. All uncertainties
84			are statistical only.}
85			\begin{tabular}{\|l\|c\|c\|c\|\|c\|}
86			\hline
87			Region & $N(ee)+N(\mu\mu)$ & $N(e\mu)$ & $R_{out/in}$ & Estimated DY BG \\
88			\hline
89	claudioc	1.3	$A'$ & 3 & 0 & 0.7$\pm$0.3 & 2.1$\pm$xx \\
90			$B'$ & 3 & 0 & 2.5$\pm$2.1 & 7.5$\pm$xx \\
91			$C'$ & 0 & 0 & 0.1$\pm$0.1 & 0$\pm$xx \\
92			$D'$ & 1 & 0 & 0.4$\pm$0.3 & 0.4$\pm$xx \\
93	claudioc	1.2	\hline
94			\end{tabular}
95			\end{center}
96			\end{table}
97	claudioc	1.1
98
99			Finally, we can use the ``Fake Rate'' method\cite{ref:FR}
100			to predict
101			the number of events with one fake lepton. We select
102			events where one of the leptons passes the full selection and
103			the other one fails the full selection but passes the
104			``Fakeable Object'' selection of
105			Reference~\cite{ref:FR}.\footnote{For electrons we use
106			the V3 fakeable object definition to avoid complications
107			associated with electron ID cuts applied in the trigger.}
108			We then weight each event passing the full selection
109			by FR/(1-FR) where FR is the ``fake rate'' for the
110			fakeable object. {\color{red} The results are...}