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\fig{ReactorTF_pic}
{ReactorTF_pic} {0.9} {System \textbf{ReactorTF}, Schematic}
Figure \Ref{fig:ReactorTF_pic} is the schematic diagram of a chemical
reactor.
The acausal bond graph of system \textbf{ReactorTF} is displayed in
Figure \Ref{fig:ReactorTF_abg.ps} and its label file is listed in
Section \Ref{sec:ReactorTF_lbl}. The subsystems are listed in Section
\Ref{sec:ReactorTF_sub}.
This example of a (nonlinear) chemical reactor is due to Trickett and
Bogle\footnote{ K. J. Tricket, \emph{Quantification of Inverse
Responses for Controllability Assessment of Nonlinear Processes},
PhD Thesis, University College London, 1994} is used in this
section. The reactor has two reaction mechanisms: $\text{A}
\rightarrow \text{B} \rightarrow \text{C}$ and $\text{2A} \rightarrow
\text{D}$. The reactor mass inflow and outflow $f_r$ are identical.
$q$ represents the heat inflow to the reactor.
The control loop $t$/$f$ has been inverted. The resulting SISO
system has two interpretations:
\begin{enumerate}
\item the \emph{dynamics} of the $c_b$/$q$ loop when the $t$/$f$ loop
is under perfect control and
\item the \emph{inverse} dynamics of the $t$/$f$ loop.
\end{enumerate}
\fig{ReactorTF_zero_1} {ReactorTF_zero_1} {0.9}
{System\textbf{ReactorTF}: zero 1 v flow}
\fig{ReactorTF_zero_2} {ReactorTF_zero_2} {0.9}
{System\textbf{ReactorTF}: zero 2 v flow}
Figures \Ref{fig:ReactorTF_zero_1} and \Ref{fig:ReactorTF_zero_2}
shows the poles of the linearised system as the steady-state flow
varies: these are the \emph{zeros} of the $t$/$f$ control-loop when
the $c_b$/$q$ loop is \emph{open}.