claudioc/OSNote2010/datadriven.tex

\section{Data Driven Background Estimation Methods}
\label{sec:datadriven}
We have developed two data-driven methods to 
estimate the background in the signal region.
The first one exploits the fact that 
SumJetPt and \met$/\sqrt{\rm SumJetPt}$ are nearly 
uncorrelated for the $t\bar{t}$ background 
(Section~\ref{sec:abcd});  the second one 
is based on the fact that in $t\bar{t}$ the
$P_T$ of the dilepton pair is on average 
nearly the same as the $P_T$ of the pair of neutrinos
from $W$-decays, which is reconstructed as \met in the
detector.


%{\color{red} I took these
%numbers from the twiki, rescaling from 11.06 to 30/pb.
%They seem too large...are they really right?}


\subsection{ABCD method}
\label{sec:abcd}

We find that in $t\bar{t}$ events SumJetPt and 
\met$/\sqrt{\rm SumJetPt}$ are nearly uncorrelated, 
as demonstrated in Figure~\ref{fig:uncor}.
Thus, we can use an ABCD method in the \met$/\sqrt{\rm SumJetPt}$ vs
sumJetPt plane to estimate the background in a data driven way.

\begin{figure}[bht]
\begin{center}
\includegraphics[width=0.75\linewidth]{uncorrelated.pdf}
\caption{\label{fig:uncor}\protect Distributions of SumJetPt 
in MC $t\bar{t}$ events for different intervals of 
MET$/\sqrt{\rm SumJetPt}$.}
\end{center}
\end{figure}

\begin{figure}[tb]
\begin{center}
\includegraphics[width=0.5\linewidth, angle=90]{abcdMC.pdf}
\caption{\label{fig:abcdMC}\protect Distributions of MET$/\sqrt{\rm SumJetPt}$ vs. 
SumJetPt for SM Monte Carlo.  Here we also show our choice of ABCD regions.}
\end{center}
\end{figure}


Our choice of ABCD regions is shown in Figure~\ref{fig:abcdMC}.
The signal region is region D.  The expected number of events 
in the four regions for the SM Monte Carlo, as well as the BG 
prediction AC/B are given in Table~\ref{tab:abcdMC} for an integrated
luminosity of 35 pb$^{-1}$.  The ABCD method is accurate 
to about 20\%. 
%{\color{red} Avi wants some statement about stability 
%wrt changes in regions.  I am not sure that we have done it and 
%I am not sure it is necessary (Claudio).}

\begin{table}[ht]
\begin{center}
\caption{\label{tab:abcdMC} Expected SM Monte Carlo yields for 
35 pb$^{-1}$ in the ABCD regions, as well as the predicted yield in
the signal region given by A $\times$ C / B. Here `SM other' is the sum
of non-dileptonic $t\bar{t}$ decays, $W^{\pm}$+jets, $W^+W^-$, 
$W^{\pm}Z^0$, $Z^0Z^0$ and single top.}
\begin{tabular}{lccccc}
\hline
         sample                          &              A   &              B   &              C   &              D   &    A $\times$ C / B \\
\hline


\hline
$t\bar{t}\rightarrow \ell^{+}\ell^{-}$   &           7.96   &          33.07   &           4.81   &           1.20   &           1.16  \\
$Z^0 \rightarrow \ell^{+}\ell^{-}$       &           0.03   &           1.47   &           0.10   &           0.10   &           0.00  \\
       SM other                          &           0.65   &           2.31   &           0.17   &           0.14   &           0.05  \\
\hline
    total SM MC                          &           8.63   &          36.85   &           5.07   &           1.43   &           1.19  \\
\hline
\end{tabular}
\end{center}
\end{table}

\subsection{Dilepton $P_T$ method}
\label{sec:victory}
This method is based on a suggestion by V. Pavlunin\cite{ref:victory},
and was investigated by our group in 2009\cite{ref:ourvictory}.
The idea is that in dilepton $t\bar{t}$ events the lepton and neutrinos
from $W$ decays have the same $P_T$ spectrum (modulo $W$ polarization 
effects).  One can then use the observed 
$P_T(\ell\ell)$ distribution to model the sum of neutrino $P_T$'s which 
is identified with the \met.

Then, in order to predict the $t\bar{t} \to$ dilepton contribution to a 
selection with \met$+$X, one applies a cut on $P_T(\ell\ell)+$X instead.
In practice one has to rescale the result of the $P_T(\ell\ell)+$X selection
to account for the fact that any dilepton selection must include a 
moderate \met cut in order to reduce Drell Yan backgrounds.  This 
is discussed in Section 5.3 of Reference~\cite{ref:ourvictory}; for a \met
cut of 50 GeV, the rescaling factor is obtained from the MC as

\newcommand{\ptll} {\ensuremath{P_T(\ell\ell)}}
\begin{center}
$ K = \frac{\int_0^{\infty} {\cal N}(\ptll)~~d\ptll~}{\int_{50}^{\infty} {\cal N}(\ptll)~~d\ptll~}$
\end{center}


Monte Carlo studies give values of $K$ that are typically between 1.5 and 1.6,
depending on selection details.   
%%%TO BE REPLACED
%Given the integrated luminosity of the
%present dataset, the determination of $K$ in data is severely statistics
%limited.  Thus, we take $K$ from $t\bar{t}$ Monte Carlo as 

%\begin{center}
%$ K_{MC} = \frac{\int_0^{\infty} {\cal N}(\met)~~d\met~}{\int_{50}^{\infty} {\cal N}(\met)~~d\met~}$
%\end{center}

%\noindent {\color{red} For the 11 pb result we have used $K$ from data.}

There are several effects that spoil the correspondance between \met and
$P_T(\ell\ell)$: 
\begin{itemize}
\item $Ws$ in top events are polarized.  Neutrinos are emitted preferentially
parallel to the $W$ velocity while charged leptons are emitted prefertially
anti-parallel. Thus the $P_T(\nu\nu)$ distribution is harder
than the $P_T(\ell\ell)$ distribution for top dilepton events.
\item The lepton selections results in $P_T$ and $\eta$ cuts on the individual
leptons that have no simple correspondance to the neutrino requirements.
\item Similarly, the \met$>$50 GeV cut introduces an asymmetry between leptons and
neutrinos which is only partially compensated by the $K$ factor above.
\item The \met resolution is much worse than the dilepton $P_T$ resolution.
When convoluted with a falling spectrum in the tails of \met, this results
in a harder spectrum for \met than the original $P_T(\nu\nu)$.
\item The \met response in CMS is not exactly 1.  This causes a distortion
in the \met distribution that is not present in the $P_T(\ell\ell)$ distribution.
\item The $t\bar{t} \to$ dilepton signal includes contributions from 
$W \to \tau \to \ell$.  For these events the arguments about the equivalence 
of $P_T(\ell\ell)$ and $P_T(\nu\nu)$ do not apply.
\item A dilepton selection will include SM events from non $t\bar{t}$ 
sources.  These events can affect the background prediction.  Particularly 
dangerous are high $P_T$ Drell Yan events that barely pass the \met$>$ 50 
GeV selection.  They will tend to push the data-driven background prediction up.
Therefore we estimate the number of DY events entering the background prediction
using the $R_{out/in}$ method as described in Sec.~\ref{sec:othBG}.
\end{itemize}

We have studied these effects in SM Monte Carlo, using a mixture of generator and
reconstruction level studies, putting the various effects in one at a time.
For each configuration, we apply the data-driven method and report as figure
of merit the ratio of observed and predicted events in the signal region.
The results are summarized in Table~\ref{tab:victorybad}.

\begin{table}[htb]
\begin{center}
\caption{\label{tab:victorybad} Test of the data driven method in Monte Carlo 
under different assumptions.  See text for details.}
\begin{tabular}{|l|c|c|c|c|c|c|c|c|}
\hline
& True $t\bar{t}$ dilepton & $t\to W\to\tau$& other SM & GEN or  & Lepton $P_T$    & Z veto & \met $>$ 50& obs/pred \\
& included                 & included       & included & RECOSIM & and $\eta$ cuts &        &            &  \\ \hline
1&Y                        &     N          &   N      &  GEN    &   N             &   N    & N          & 1.90  \\
2&Y                        &     N          &   N      &  GEN    &   Y             &   N    & N          & 1.64  \\
3&Y                        &     N          &   N      &  GEN    &   Y             &   Y    & N          & 1.59  \\
4&Y                        &     N          &   N      &  GEN    &   Y             &   Y    & Y          & 1.55  \\
5&Y                        &     N          &   N      & RECOSIM &   Y             &   Y    & Y          & 1.51  \\
6&Y                        &     Y          &   N      & RECOSIM &   Y             &   Y    & Y          & 1.58  \\
7&Y                        &     Y          &   Y      & RECOSIM &   Y             &   Y    & Y          & 1.38  \\
%%%NOTE: updated value 1.18 -> 1.46 since 2/3 DY events have been removed by updated analysis selections,
%%%dpt/pt cut and general lepton veto
\hline
\end{tabular}
\end{center}
\end{table}


The largest discrepancy between prediction and observation occurs on the first 
line of Table~\ref{tab:victorybad}, {\em i.e.}, at the generator level with no
cuts.  We have verified that this effect is due to the polarization of
the $W$ (we remove the polarization by reweighting the events and we get
good agreement between prediction and observation).  The kinematical 
requirements (lines 2,3,4) compensate somewhat for the effect of W polarization. 
Going from GEN to RECOSIM, the change in observed/predicted is small.  
% We have tracked this down to the fact that tcMET underestimates the true \met
% by $\approx 4\%$\footnote{We find that observed/predicted changes by roughly 0.1
%for each 1.5\% change in \met response.}.  
Finally, contamination from non $t\bar{t}$
events can have a significant impact on the BG prediction.  
%The changes between 
%lines 6 and 7 of Table~\ref{tab:victorybad} is driven by 3
%Drell Yan events that pass the \met selection in Monte Carlo (thus the effect
%is statistically not well quantified).

An additional source of concern is that the CMS Madgraph $t\bar{t}$ MC does
not include effects of spin correlations between the two top quarks.  
We have studied this effect at the generator level using Alpgen.  We find
that the bias is at the few percent level.

%%%TO BE REPLACED
%Based on the results of Table~\ref{tab:victorybad}, we conclude that the 
%naive data driven background estimate based on $P_T{(\ell\ell)}$ needs to 
%be corrected by a factor of {\color{red} $ K_{\rm{fudge}} =1.2 \pm 0.3$ 
%(We still need to settle on thie exact value of this.
%For the 11 pb analysis it is taken as =1.)} . The quoted 
%uncertainty is based on the stability of the Monte Carlo tests under 
%variations of event selections, choices of \met algorithm, etc.
%For example, we find that observed/predicted changes by roughly 0.1
%for each 1.5\% change in the average \met response.  

Based on the results of Table~\ref{tab:victorybad}, we conclude that the 
naive data driven background estimate based on $P_T{(\ell\ell)}$ needs to 
be corrected by a factor of $ K_C = X \pm Y$.
The value of this correction factor as well as the systematic uncertainty
will be assessed using 38X ttbar madgraph MC. In the following we use
$K_C = 1$ for simplicity. Based on previous MC studies we foresee a correction
factor of $K_C \approx 1.2 - 1.5$, and we will assess an uncertainty
based on the stability of the Monte Carlo tests under 
variations of event selections, choices of \met algorithm, etc.
For example, we find that observed/predicted changes by roughly 0.1
for each 1.5\% change in the average \met response. 


\subsection{Signal Contamination}
\label{sec:sigcont}

All data-driven methods are in principle subject to signal contaminations
in the control regions, and the methods described in 
Sections~\ref{sec:abcd} and~\ref{sec:victory} are not exceptions.
Signal contamination tends to dilute the significance of a signal
present in the data by inflating the background prediction.

It is hard to quantify how important these effects are because we 
do not know what signal may be hiding in the data.  Having two
independent methods (in addition to Monte Carlo ``dead-reckoning'')
adds redundancy because signal contamination can have different effects
in the different control regions for the two methods.
For example, in the extreme case of a
new physics signal 
with $P_T(\ell \ell) = \met$, an excess of events would be seen 
in the ABCD method but not in the $P_T(\ell \ell)$ method.


The LM points are benchmarks for SUSY analyses at CMS.  The effects
of signal contaminations for a couple such points are summarized
in Table~\ref{tab:sigcont}. Signal contamination is definitely an important
effect for these two LM points, but it does not totally hide the
presence of the signal.


\begin{table}[htb]
\begin{center}
\caption{\label{tab:sigcont} Effects of signal contamination 
for the two data-driven background estimates. The three columns give
the expected yield in the signal region and the background estimates
using the ABCD and $P_T(\ell \ell)$ methods. Results are normalized to 35~pb$^{-1}$.}
\begin{tabular}{lccc}
\hline
            &      Yield      &      ABCD    & $P_T(\ell \ell)$  \\
\hline
SM only     &      1.43       &      1.19    &             1.03  \\
SM + LM0    &      7.90       &      4.23    &             2.35  \\
SM + LM1    &      4.00       &      1.53    &             1.51  \\
\hline
\end{tabular}
\end{center}
\end{table}


%\begin{table}[htb]
%\begin{center}
%\caption{\label{tab:sigcontABCD} Effects of signal contamination 
%for the background predictions of the ABCD method including LM0 or 
%LM1.  Results
%are normalized to 30 pb$^{-1}$.}
%\begin{tabular}{|c|c||c|c||c|c|}
%\hline
%SM         & BG Prediction  & SM$+$LM0     & BG Prediction & SM$+$LM1     & BG Prediction \\
%Background & SM Only        & Contribution & Including LM0 & Contribution & Including LM1  \\ \hline
%1.2        & 1.0            & 6.8          & 3.7           & 3.4          & 1.3 \\ 
%\hline
%\end{tabular}
%\end{center}
%\end{table}

%\begin{table}[htb]
%\begin{center}
%\caption{\label{tab:sigcontPT} Effects of signal contamination 
%for the background predictions of the $P_T(\ell\ell)$ method including LM0 or 
%LM1.  Results
%are normalized to 30 pb$^{-1}$.} 
%\begin{tabular}{|c|c||c|c||c|c|}
%\hline
%SM         & BG Prediction  & SM$+$LM0     & BG Prediction & SM$+$LM1     & BG Prediction \\
%Background & SM Only        & Contribution & Including LM0 & Contribution & Including LM1  \\ \hline
%1.2        & 1.0            & 6.8          & 2.2           & 3.4          & 1.5 \\ 
%\hline
%\end{tabular}
%\end{center}
%\end{table}

Revision:	1.22
Committed:	Mon Nov 15 10:07:57 2010 UTC (14 years, 5 months ago) by benhoob
Content type:	application/x-tex
Branch:	MAIN
Changes since 1.21:	+6 -6 lines
Log Message:	Minor updates
#	Content
1	\section{Data Driven Background Estimation Methods}
2	\label{sec:datadriven}
3	We have developed two data-driven methods to
4	estimate the background in the signal region.
5	The first one exploits the fact that
6	SumJetPt and \met$/\sqrt{\rm SumJetPt}$ are nearly
7	uncorrelated for the $t\bar{t}$ background
8	(Section~\ref{sec:abcd}); the second one
9	is based on the fact that in $t\bar{t}$ the
10	$P_T$ of the dilepton pair is on average
11	nearly the same as the $P_T$ of the pair of neutrinos
12	from $W$-decays, which is reconstructed as \met in the
13	detector.
14
15
16	%{\color{red} I took these
17	%numbers from the twiki, rescaling from 11.06 to 30/pb.
18	%They seem too large...are they really right?}
19
20
21	\subsection{ABCD method}
22	\label{sec:abcd}
23
24	We find that in $t\bar{t}$ events SumJetPt and
25	\met$/\sqrt{\rm SumJetPt}$ are nearly uncorrelated,
26	as demonstrated in Figure~\ref{fig:uncor}.
27	Thus, we can use an ABCD method in the \met$/\sqrt{\rm SumJetPt}$ vs
28	sumJetPt plane to estimate the background in a data driven way.
29
30	\begin{figure}[bht]
31	\begin{center}
32	\includegraphics[width=0.75\linewidth]{uncorrelated.pdf}
33	\caption{\label{fig:uncor}\protect Distributions of SumJetPt
34	in MC $t\bar{t}$ events for different intervals of
35	MET$/\sqrt{\rm SumJetPt}$.}
36	\end{center}
37	\end{figure}
38
39	\begin{figure}[tb]
40	\begin{center}
41	\includegraphics[width=0.5\linewidth, angle=90]{abcdMC.pdf}
42	\caption{\label{fig:abcdMC}\protect Distributions of MET$/\sqrt{\rm SumJetPt}$ vs.
43	SumJetPt for SM Monte Carlo. Here we also show our choice of ABCD regions.}
44	\end{center}
45	\end{figure}
46
47
48	Our choice of ABCD regions is shown in Figure~\ref{fig:abcdMC}.
49	The signal region is region D. The expected number of events
50	in the four regions for the SM Monte Carlo, as well as the BG
51	prediction AC/B are given in Table~\ref{tab:abcdMC} for an integrated
52	luminosity of 35 pb$^{-1}$. The ABCD method is accurate
53	to about 20\%.
54	%{\color{red} Avi wants some statement about stability
55	%wrt changes in regions. I am not sure that we have done it and
56	%I am not sure it is necessary (Claudio).}
57
58	\begin{table}[ht]
59	\begin{center}
60	\caption{\label{tab:abcdMC} Expected SM Monte Carlo yields for
61	35 pb$^{-1}$ in the ABCD regions, as well as the predicted yield in
62	the signal region given by A $\times$ C / B. Here `SM other' is the sum
63	of non-dileptonic $t\bar{t}$ decays, $W^{\pm}$+jets, $W^+W^-$,
64	$W^{\pm}Z^0$, $Z^0Z^0$ and single top.}
65	\begin{tabular}{lccccc}
66	\hline
67	sample & A & B & C & D & A $\times$ C / B \\
68	\hline
69
70
71	\hline
72	$t\bar{t}\rightarrow \ell^{+}\ell^{-}$ & 7.96 & 33.07 & 4.81 & 1.20 & 1.16 \\
73	$Z^0 \rightarrow \ell^{+}\ell^{-}$ & 0.03 & 1.47 & 0.10 & 0.10 & 0.00 \\
74	SM other & 0.65 & 2.31 & 0.17 & 0.14 & 0.05 \\
75	\hline
76	total SM MC & 8.63 & 36.85 & 5.07 & 1.43 & 1.19 \\
77	\hline
78	\end{tabular}
79	\end{center}
80	\end{table}
81
82	\subsection{Dilepton $P_T$ method}
83	\label{sec:victory}
84	This method is based on a suggestion by V. Pavlunin\cite{ref:victory},
85	and was investigated by our group in 2009\cite{ref:ourvictory}.
86	The idea is that in dilepton $t\bar{t}$ events the lepton and neutrinos
87	from $W$ decays have the same $P_T$ spectrum (modulo $W$ polarization
88	effects). One can then use the observed
89	$P_T(\ell\ell)$ distribution to model the sum of neutrino $P_T$'s which
90	is identified with the \met.
91
92	Then, in order to predict the $t\bar{t} \to$ dilepton contribution to a
93	selection with \met$+$X, one applies a cut on $P_T(\ell\ell)+$X instead.
94	In practice one has to rescale the result of the $P_T(\ell\ell)+$X selection
95	to account for the fact that any dilepton selection must include a
96	moderate \met cut in order to reduce Drell Yan backgrounds. This
97	is discussed in Section 5.3 of Reference~\cite{ref:ourvictory}; for a \met
98	cut of 50 GeV, the rescaling factor is obtained from the MC as
99
100	\newcommand{\ptll} {\ensuremath{P_T(\ell\ell)}}
101	\begin{center}
102	$ K = \frac{\int_0^{\infty} {\cal N}(\ptll)~~d\ptll~}{\int_{50}^{\infty} {\cal N}(\ptll)~~d\ptll~}$
103	\end{center}
104
105
106	Monte Carlo studies give values of $K$ that are typically between 1.5 and 1.6,
107	depending on selection details.
108	%%%TO BE REPLACED
109	%Given the integrated luminosity of the
110	%present dataset, the determination of $K$ in data is severely statistics
111	%limited. Thus, we take $K$ from $t\bar{t}$ Monte Carlo as
112
113	%\begin{center}
114	%$ K_{MC} = \frac{\int_0^{\infty} {\cal N}(\met)~~d\met~}{\int_{50}^{\infty} {\cal N}(\met)~~d\met~}$
115	%\end{center}
116
117	%\noindent {\color{red} For the 11 pb result we have used $K$ from data.}
118
119	There are several effects that spoil the correspondance between \met and
120	$P_T(\ell\ell)$:
121	\begin{itemize}
122	\item $Ws$ in top events are polarized. Neutrinos are emitted preferentially
123	parallel to the $W$ velocity while charged leptons are emitted prefertially
124	anti-parallel. Thus the $P_T(\nu\nu)$ distribution is harder
125	than the $P_T(\ell\ell)$ distribution for top dilepton events.
126	\item The lepton selections results in $P_T$ and $\eta$ cuts on the individual
127	leptons that have no simple correspondance to the neutrino requirements.
128	\item Similarly, the \met$>$50 GeV cut introduces an asymmetry between leptons and
129	neutrinos which is only partially compensated by the $K$ factor above.
130	\item The \met resolution is much worse than the dilepton $P_T$ resolution.
131	When convoluted with a falling spectrum in the tails of \met, this results
132	in a harder spectrum for \met than the original $P_T(\nu\nu)$.
133	\item The \met response in CMS is not exactly 1. This causes a distortion
134	in the \met distribution that is not present in the $P_T(\ell\ell)$ distribution.
135	\item The $t\bar{t} \to$ dilepton signal includes contributions from
136	$W \to \tau \to \ell$. For these events the arguments about the equivalence
137	of $P_T(\ell\ell)$ and $P_T(\nu\nu)$ do not apply.
138	\item A dilepton selection will include SM events from non $t\bar{t}$
139	sources. These events can affect the background prediction. Particularly
140	dangerous are high $P_T$ Drell Yan events that barely pass the \met$>$ 50
141	GeV selection. They will tend to push the data-driven background prediction up.
142	Therefore we estimate the number of DY events entering the background prediction
143	using the $R_{out/in}$ method as described in Sec.~\ref{sec:othBG}.
144	\end{itemize}
145
146	We have studied these effects in SM Monte Carlo, using a mixture of generator and
147	reconstruction level studies, putting the various effects in one at a time.
148	For each configuration, we apply the data-driven method and report as figure
149	of merit the ratio of observed and predicted events in the signal region.
150	The results are summarized in Table~\ref{tab:victorybad}.
151
152	\begin{table}[htb]
153	\begin{center}
154	\caption{\label{tab:victorybad} Test of the data driven method in Monte Carlo
155	under different assumptions. See text for details.}
156	\begin{tabular}{\|l\|c\|c\|c\|c\|c\|c\|c\|c\|}
157	\hline
158	& True $t\bar{t}$ dilepton & $t\to W\to\tau$& other SM & GEN or & Lepton $P_T$ & Z veto & \met $>$ 50& obs/pred \\
159	& included & included & included & RECOSIM & and $\eta$ cuts & & & \\ \hline
160	1&Y & N & N & GEN & N & N & N & 1.90 \\
161	2&Y & N & N & GEN & Y & N & N & 1.64 \\
162	3&Y & N & N & GEN & Y & Y & N & 1.59 \\
163	4&Y & N & N & GEN & Y & Y & Y & 1.55 \\
164	5&Y & N & N & RECOSIM & Y & Y & Y & 1.51 \\
165	6&Y & Y & N & RECOSIM & Y & Y & Y & 1.58 \\
166	7&Y & Y & Y & RECOSIM & Y & Y & Y & 1.38 \\
167	%%%NOTE: updated value 1.18 -> 1.46 since 2/3 DY events have been removed by updated analysis selections,
168	%%%dpt/pt cut and general lepton veto
169	\hline
170	\end{tabular}
171	\end{center}
172	\end{table}
173
174
175	The largest discrepancy between prediction and observation occurs on the first
176	line of Table~\ref{tab:victorybad}, {\em i.e.}, at the generator level with no
177	cuts. We have verified that this effect is due to the polarization of
178	the $W$ (we remove the polarization by reweighting the events and we get
179	good agreement between prediction and observation). The kinematical
180	requirements (lines 2,3,4) compensate somewhat for the effect of W polarization.
181	Going from GEN to RECOSIM, the change in observed/predicted is small.
182	% We have tracked this down to the fact that tcMET underestimates the true \met
183	% by $\approx 4\%$\footnote{We find that observed/predicted changes by roughly 0.1
184	%for each 1.5\% change in \met response.}.
185	Finally, contamination from non $t\bar{t}$
186	events can have a significant impact on the BG prediction.
187	%The changes between
188	%lines 6 and 7 of Table~\ref{tab:victorybad} is driven by 3
189	%Drell Yan events that pass the \met selection in Monte Carlo (thus the effect
190	%is statistically not well quantified).
191
192	An additional source of concern is that the CMS Madgraph $t\bar{t}$ MC does
193	not include effects of spin correlations between the two top quarks.
194	We have studied this effect at the generator level using Alpgen. We find
195	that the bias is at the few percent level.
196
197	%%%TO BE REPLACED
198	%Based on the results of Table~\ref{tab:victorybad}, we conclude that the
199	%naive data driven background estimate based on $P_T{(\ell\ell)}$ needs to
200	%be corrected by a factor of {\color{red} $ K_{\rm{fudge}} =1.2 \pm 0.3$
201	%(We still need to settle on thie exact value of this.
202	%For the 11 pb analysis it is taken as =1.)} . The quoted
203	%uncertainty is based on the stability of the Monte Carlo tests under
204	%variations of event selections, choices of \met algorithm, etc.
205	%For example, we find that observed/predicted changes by roughly 0.1
206	%for each 1.5\% change in the average \met response.
207
208	Based on the results of Table~\ref{tab:victorybad}, we conclude that the
209	naive data driven background estimate based on $P_T{(\ell\ell)}$ needs to
210	be corrected by a factor of $ K_C = X \pm Y$.
211	The value of this correction factor as well as the systematic uncertainty
212	will be assessed using 38X ttbar madgraph MC. In the following we use
213	$K_C = 1$ for simplicity. Based on previous MC studies we foresee a correction
214	factor of $K_C \approx 1.2 - 1.5$, and we will assess an uncertainty
215	based on the stability of the Monte Carlo tests under
216	variations of event selections, choices of \met algorithm, etc.
217	For example, we find that observed/predicted changes by roughly 0.1
218	for each 1.5\% change in the average \met response.
219
220
221
222	\subsection{Signal Contamination}
223	\label{sec:sigcont}
224
225	All data-driven methods are in principle subject to signal contaminations
226	in the control regions, and the methods described in
227	Sections~\ref{sec:abcd} and~\ref{sec:victory} are not exceptions.
228	Signal contamination tends to dilute the significance of a signal
229	present in the data by inflating the background prediction.
230
231	It is hard to quantify how important these effects are because we
232	do not know what signal may be hiding in the data. Having two
233	independent methods (in addition to Monte Carlo ``dead-reckoning'')
234	adds redundancy because signal contamination can have different effects
235	in the different control regions for the two methods.
236	For example, in the extreme case of a
237	new physics signal
238	with $P_T(\ell \ell) = \met$, an excess of events would be seen
239	in the ABCD method but not in the $P_T(\ell \ell)$ method.
240
241
242	The LM points are benchmarks for SUSY analyses at CMS. The effects
243	of signal contaminations for a couple such points are summarized
244	in Table~\ref{tab:sigcont}. Signal contamination is definitely an important
245	effect for these two LM points, but it does not totally hide the
246	presence of the signal.
247
248
249	\begin{table}[htb]
250	\begin{center}
251	\caption{\label{tab:sigcont} Effects of signal contamination
252	for the two data-driven background estimates. The three columns give
253	the expected yield in the signal region and the background estimates
254	using the ABCD and $P_T(\ell \ell)$ methods. Results are normalized to 35~pb$^{-1}$.}
255	\begin{tabular}{lccc}
256	\hline
257	& Yield & ABCD & $P_T(\ell \ell)$ \\
258	\hline
259	SM only & 1.43 & 1.19 & 1.03 \\
260	SM + LM0 & 7.90 & 4.23 & 2.35 \\
261	SM + LM1 & 4.00 & 1.53 & 1.51 \\
262	\hline
263	\end{tabular}
264	\end{center}
265	\end{table}
266
267
268
269	%\begin{table}[htb]
270	%\begin{center}
271	%\caption{\label{tab:sigcontABCD} Effects of signal contamination
272	%for the background predictions of the ABCD method including LM0 or
273	%LM1. Results
274	%are normalized to 30 pb$^{-1}$.}
275	%\begin{tabular}{\|c\|c\|\|c\|c\|\|c\|c\|}
276	%\hline
277	%SM & BG Prediction & SM$+$LM0 & BG Prediction & SM$+$LM1 & BG Prediction \\
278	%Background & SM Only & Contribution & Including LM0 & Contribution & Including LM1 \\ \hline
279	%1.2 & 1.0 & 6.8 & 3.7 & 3.4 & 1.3 \\
280	%\hline
281	%\end{tabular}
282	%\end{center}
283	%\end{table}
284
285	%\begin{table}[htb]
286	%\begin{center}
287	%\caption{\label{tab:sigcontPT} Effects of signal contamination
288	%for the background predictions of the $P_T(\ell\ell)$ method including LM0 or
289	%LM1. Results
290	%are normalized to 30 pb$^{-1}$.}
291	%\begin{tabular}{\|c\|c\|\|c\|c\|\|c\|c\|}
292	%\hline
293	%SM & BG Prediction & SM$+$LM0 & BG Prediction & SM$+$LM1 & BG Prediction \\
294	%Background & SM Only & Contribution & Including LM0 & Contribution & Including LM1 \\ \hline
295	%1.2 & 1.0 & 6.8 & 2.2 & 3.4 & 1.5 \\
296	%\hline
297	%\end{tabular}
298	%\end{center}
299	%\end{table}
300