sneaky snoopy

submission_thesis/CH5_Examples/software.tex

@@ -33,7 +33,8 @@ When we have analysed a software function---using failure conditions
 of its inputs as failure modes---we can 
 determine its symptoms of failure (i.e. how calling functions will see its failure mode behaviour).
 
-We can thus apply the $\derivec$ process to software functions, by viewing them in terms of their failure
+We can thus apply the FMMD % $\derivec$ 
+process to software functions, by viewing them in terms of their failure
 mode behaviour. To simplify things as well, software already fits into a hierarchy.
 For Electronics and Mechanical systems, although we may be guided by the original designers
 concepts of modularity and sub-systems in design, applying FMMD means deciding on the members for {\fgs}
@@ -410,8 +411,8 @@ With these failure modes, we can analyse our first functional group, see table~\
 We now collect the symptoms for the hardware functional group, $\{ HIGH , LOW, V\_ERR \} $.
 We now create a {\dc} to represent this called $CMATV$.
 
-We can express this using the `$\derivec$' function thus:
-$$ CMATV = \; \derivec (G_1) .$$
+%We can express this using the `$\derivec$' function thus:
+%$$ CMATV = \; \derivec (G_1) .$$
 
 As its failure modes, are the symptoms of failure from the functional group we can now state:
 $$fm ( CMATV ) =  \{ HIGH , LOW, V\_ERR \} .$$
@@ -502,9 +503,9 @@ for the function.
 This postcondition, {\em /* ensure: value is voltage input to within 0.1\% */ },
 corresponds to $VV\_ERR$, and is already in the {\fm} set for this {\fg}.
 
-We can now create a {\dc} called $RADC$ thus: $$RADC = \; \derivec(G_2)$$ which has the following
-{\fms}:
-
+%We can now create a {\dc} called $RADC$ thus: $$RADC = \; \derivec(G_2)$$ which has the following
+%{\fms}:
+We can now create a {\dc} called $RADC$ thus:
 $$ fm(RADC) = \{ VV\_ERR, HIGH, LOW \} .$$
 
 
@@ -575,9 +576,9 @@ For single failures these are the two ways in which this function
 can fail. An $OUT\_OF\_RANGE$ will be flagged by the error flag variable.
 The $VAL\_ERR$ will simply mean that the value read is incorrect.
 
-We can finally make a {\dc} to represent a failure mode model for our function $read\_4\_20\_input$ thus:
+We can finally make a {\dc} to represent a failure mode model for our function $read\_4\_20\_input$. %thus:
 
-$$ R420I = \; \derivec(G_3) .$$
+% $$ R420I = \; \derivec(G_3) .$$
 
 This new {\dc} has the following {\fms}:
 $$fm(R420I) = \{OUT\_OF\_RANGE, VAL\_ERR\} .$$
@@ -612,7 +613,7 @@ as a hierarchical diagram, see figure~\ref{fig:eulerswhw}. % see figure~\ref{fig
 \end{figure}
 
 
-
+% HTR == HATE TO REMOVE
 %HTR 18NOV2012 We can represent %the hierarchy in figure~\ref{fig:hd} algebraically, 
 %HTR 18NOV2012 the analysis hierarchy algebraically using the `$\derivec$' function:
 %HTR 18NOV2012 %using the groups as intermediate stages: