fixups

content.tex

@@ -15,7 +15,6 @@
 \section{Nominal Techniques}
 \component content/test-methods
 \component content/applying-automata-learning
-\chapter{Learning Embedded Stuff}
 \chapter{Separating Sequences}
 \component content/learning-nominal-automata
 \chapter{Ordered Nominal Sets}

content/learning-nominal-automata.tex

@@ -184,7 +184,7 @@ The table is closed and consistent, so we construct the hypothesis $\autom_1$.
 \stoptikzpicture
 \starttikzpicture
 \node[initial,state,initial text={$\autom_1 = $}] (q0) {$q_0$};
-\path (q0) edge[loop right] node[trlab,right] {$a,b$} (q0);
+\path (q0) edge[loop right] node[right] {$a,b$} (q0);
 \stoptikzpicture
 \startformula
 q_0 = row(\epsilon) = \{ \epsilon \mapsto 0 \}
@@ -246,11 +246,11 @@ The new table is closed and consistent and a new hypothesis $\autom_2$ is constr
 \node[state,accepting,below of=q1] (q2) {$q_2$};
 
 \path[->]
-(q0) edge[loop below] node[trlab,below] {$b$} (q0)
+(q0) edge[loop below] node[below] {$b$} (q0)
-(q0) edge[bend right] node[trlab,above] {$a$} (q1)
+(q0) edge[bend right] node[above] {$a$} (q1)
-(q1) edge[bend right] node[trlab,above] {$b$} (q0)
+(q1) edge[bend right] node[above] {$b$} (q0)
-(q1) edge node[trlab,right] {$a$} (q2)
+(q1) edge node[right] {$a$} (q2)
-(q2) edge node[trlab,midway,fill=white] {$a, b$} (q0);
+(q2) edge node[midway,fill=white] {$a, b$} (q0);
 \stoptikzpicture
 
 The Teacher again replies {\bf no} and gives the counterexample $bb$, which should be accepted by $\autom_2$ but it is not. Therefore we put $S \gets S \cup \{b,bb\}$.
@@ -316,13 +316,13 @@ The new hypothesis is $\autom_3$.
 \node[state,accepting,right of=q2] (q3) {$q_3$};	
 
 \path[->]
-(q0) edge[bend left] node[trlab,above] {$a$} (q1)
+(q0) edge[bend left] node[above] {$a$} (q1)
-(q1) edge[bend left] node[trlab,above] {$b$} (q0)
+(q1) edge[bend left] node[above] {$b$} (q0)
-(q1) edge node[trlab,right] {$a$} (q3)
+(q1) edge node[right] {$a$} (q3)
-(q0) edge[bend right] node[trlab,left] {$b$} (q2)
+(q0) edge[bend right] node[left] {$b$} (q2)
-(q2) edge[bend right] node[trlab,left] {$a$} (q0)
+(q2) edge[bend right] node[left] {$a$} (q0)
-(q2) edge node[trlab,above] {$b$} (q3)
+(q2) edge node[above] {$b$} (q3)
-(q3) edge node[trlab,fill=white,midway] {$a,b$} (q0);
+(q3) edge node[fill=white,midway] {$a,b$} (q0);
 \stoptikzpicture
 
 The Teacher replies {\bf no} and provides the counterexample $babb$, so $S \gets S \cup \{ba,bab\}$.
@@ -339,14 +339,14 @@ One more step brings us to the correct hypothesis $\autom_4$ (details are omitte
 \node[state,right of=q3] (q4) {$q_4$};
 
 \path[->]
-(q0) edge node[trlab,above left] {$a$} (q1)
+(q0) edge node[above left] {$a$} (q1)
-(q1) edge node[trlab,above right] {$a$} (q3)
+(q1) edge node[above right] {$a$} (q3)
-(q0) edge node[trlab,below left] {$b$} (q2)
+(q0) edge node[below left] {$b$} (q2)
-(q2) edge node[trlab,below right] {$b$} (q3)
+(q2) edge node[below right] {$b$} (q3)
-(q1) edge[bend left] node[trlab,above] {$b$} (q4)
+(q1) edge[bend left] node[above] {$b$} (q4)
-(q3) edge node[trlab,above] {$a,b$} (q4)
+(q3) edge node[above] {$a,b$} (q4)
-(q2) edge[bend right] node[trlab,below] {$a$} (q4)
+(q2) edge[bend right] node[below] {$a$} (q4)
-(q4) edge[loop right] node[trlab,right] {$a,b$} (q4);
+(q4) edge[loop right] node[right] {$a,b$} (q4);
 \stoptikzpicture
 
 \stopstep
@@ -370,17 +370,17 @@ Classical theory of finite automata does not apply to this kind of languages, bu
 \node[state,right of=q3] (q4) {$q_4$};
 
 \path[->]
-(q0) edge node[trlab,above left] {$a$} (qa)
+(q0) edge node[above left] {$a$} (qa)
-(qa) edge node[trlab,above right] {$a$} (q3)
+(qa) edge node[above right] {$a$} (q3)
-(q0) edge node[trlab,above] {$b$} (qb)
+(q0) edge node[above] {$b$} (qb)
-(qb) edge node[trlab,above] {$b$} (q3)
+(qb) edge node[above] {$b$} (q3)
-(q0) edge node[trlab] {} (qdots)
+(q0) edge node {} (qdots)
-(qdots) edge node[trlab] {} (q3)
+(qdots) edge node {} (q3)
-(qa) edge[bend left] node[trlab,above] {${\neq} a$} (q4)
+(qa) edge[bend left] node[above] {${\neq} a$} (q4)
-(q3) edge node[trlab,above] {$A$} (q4)
+(q3) edge node[above] {$A$} (q4)
-(qb) edge[bend right] node[trlab,below] {${\neq} b$} (q4)
+(qb) edge[bend right] node[below] {${\neq} b$} (q4)
-(qdots) edge[bend right] node[trlab] {} (q4)
+(qdots) edge[bend right] node {} (q4)
-(q4) edge[loop right] node[trlab,right] {$A$} (q4);
+(q4) edge[loop right] node[right] {$A$} (q4);
 \stoptikzpicture
 
 where $\tot{A}$ and $\tot{{\neq} a}$ stand for the infinitely-many transitions labelled by elements of $A$ and $A \setminus \{a\}$, respectively.
@@ -391,14 +391,14 @@ This automaton is infinite, but it can be finitely presented in a variety of way
 \node[state, right of=q0] (qx) {$q_x$};
 \node[state,accepting,right of=qx] (q3) {$q_3$};
 \node[state,right of=q3] (q4) {$q_4$};
-\node[above = 0pt of qx] (qa) {\scriptsize{$\forall x \in A$}};
+\node[above = 0pt of qx] (qa) {$\forall x \in A$};
 
 \path[->]
-(q0) edge node[trlab,above] {$x$} (qx)
+(q0) edge node[above] {$x$} (qx)
-(qx) edge node[trlab,above] {$x$} (q3)
+(qx) edge node[above] {$x$} (q3)
-(q3) edge node[trlab,above] {$A$} (q4)
+(q3) edge node[above] {$A$} (q4)
-(qx) edge[bend right] node[trlab,below] {${\neq} x$} (q4)
+(qx) edge[bend right] node[below] {${\neq} x$} (q4)
-(q4) edge[loop right] node[trlab,right] {$A$} (q4);
+(q4) edge[loop right] node[right] {$A$} (q4);
 \stoptikzpicture
 
 One can formalize the quantifier notation above (or indeed the \quotation{dots} notation above that) in  several ways.
@@ -470,7 +470,7 @@ Then, by {\bf (P2)}, $row(\pi(a))(\epsilon) = row(a)(\epsilon) = 0$, for all $\p
 \stoptikzpicture
 \starttikzpicture
 \node[initial,state,initial text={$\autom'_1 = $}] (q0) {$q_0$};
-\path (q0) edge[loop right] node[trlab,right] {$A$} (q0);
+\path (q0) edge[loop right] node[right] {$A$} (q0);
 \stoptikzpicture
 
 It is closed and consistent.
@@ -543,10 +543,10 @@ The hypothesis automaton is
 \node[right of=q2] (dummy) {$\forall x \in A$};
 
 \path[->]
-(q0) edge[bend left] node[trlab,above] {$x$} (qx)
+(q0) edge[bend left] node[above] {$x$} (qx)
-(qx) edge[bend left] node[trlab,above] {$\neq x$} (q0)
+(qx) edge[bend left] node[above] {$\neq x$} (q0)
-(qx) edge node[trlab,above] {$x$} (q2)
+(qx) edge node[above] {$x$} (q2)
-(q2) edge[bend right=50] node[trlab,below] {$A$} (q0);
+(q2) edge[bend right=50] node[below] {$A$} (q0);
 \stoptikzpicture
 
 This is again incorrect, but one additional step will give the correct hypothesis automaton, shown earlier in \in{?}[eq:aut]).
@@ -698,7 +698,7 @@ The learning algorithm for nominal automata, \nLStar{}, will be very similar to
 In fact, we only change the following lines:
 \placeformula[eq:changes]
 \startformula[interlinespace=small]\startmathmatrix[n=2, align={middle, left}, distance=1cm]
-\NC \text{\color[darkgray]{7'}    \NC S \gets S \cup \orb(sa)        \NR
+\NC \text{\color[darkgray]{7'}}   \NC S \gets S \cup \orb(sa)       \NR
 \NC \text{\color[darkgray]{11'}}  \NC E \gets E \cup \orb(ae)       \NR
 \NC \text{\color[darkgray]{16'}}  \NC S \gets S \cup \pref(\orb(t)) \NR
 \stopmathmatrix\stopformula