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-rw-r--r--frsb_kac-rice.tex20
1 files changed, 12 insertions, 8 deletions
diff --git a/frsb_kac-rice.tex b/frsb_kac-rice.tex
index ca87ee5..c9c9ce8 100644
--- a/frsb_kac-rice.tex
+++ b/frsb_kac-rice.tex
@@ -431,7 +431,16 @@ The second equation implies
\subsection{Motivation}
-The reader who is happy with the ansatz may skip this section.
+We shall make the following ansatz
+to putting:
+\begin{eqnarray}
+Q_{ab}&=& {\mbox{ a Parisi matrix}}\nonumber\\
+R_{ab}&=&R_d \delta_{ab}&\nonumber\\
+D_{ab}&=& D_d \delta_{ab}\label{ansatz}
+\end{eqnarray}
+This ansatz closes under the operations that are involved in the replicated action.
+The reader who is happy with the ansatz may skip the rest of this section.
+
We may encode the original variables in a superspace variable:
\begin{equation}
\phi_a(1)= s_a + \bar\eta_a\theta_1+\bar\theta_1\eta_a + \hat s_a \bar \theta_1 \theta_1
@@ -466,13 +475,8 @@ The odd and even fermion numbers decouple, so we can neglect all odd terms in $\
The variables $\bar \theta \theta$ and $\bar \theta ' \theta'$ play
the role of `times' in a superspace treatment. We have a long experience of
making an ansatz for replicated quantum problems, which naturally involve a (Matsubara) time. The analogy strongly
-suggests that only the diagonal ${\bf Q}_{aa}$ depend on the $\theta$'s. This boils down
-to putting:
-\begin{eqnarray}
-Q_{ab}&=& {\mbox{ a Parisi matrix}}\nonumber\\
-R_{ab}&=R_d \delta_{ab}&\nonumber\\
-D_{ab}&=& D_d \delta_{ab}
-\end{eqnarray}
+suggests that only the diagonal ${\bf Q}_{aa}$ depend on the $\theta$'s. This boils down the ansatz \ref{ansatz}
+
Not surprisingly, this ansatz closes, as we shall see. That it closes under Hadamard products is simple.
\begin{equation}