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Lecture 5 NFA with epsilon moves

  Definition and example of a NFA with epsilon transitions.
  Remember, epsilon is the zero length string, so it can be any where
  in the input string, front, back, between any symbols.

  There is a conversion algorithm from a NFA with epsilon transitions to
  a NFA without epsilon transitions.

  Consider the NFA-epsilon move machine M = { Q, sigma, delta, q0, F}
  Q = { q0, q1, q2 }
  sigma = { a, b, c }  and epsilon moves
  q0 = q0
  F = { q2 }

                         sigma plus epsilon

     delta          |  a   |  b   |  c   |epsilon
              ------+------+------+------+-------
                q0  | {q0} | phi  | phi  | {q1}
              ------+------+------+------+-------
                q1  | phi  | {q2} | phi  | {q2}
              ------+------+------+------+-------
                q2  | phi  | phi  | {q2} | phi
              ------+------+------+------+-------
Note: add an arc from qz to qz labeled "c" to figure above.

  The language accepted by the above NFA with epsilon moves is
  the set of strings over {a,b,c} including the null string and
  all strings with any number of a's followed by any number of b's
  followed by any number of c's.

  Now convert the NFA with epsilon moves to a NFA M = ( Q', sigma, delta', q0', F')
  First determine the states of the new machine, Q' = the epsilon closure
  of the states in the NFA with epsilon moves. There will be the same number
  of states but the names can be constructed by writing the state name as
  the set of states in the epsilon closure. The epsilon closure is the
  initial state and all states that can be reached by one or more epsilon moves.
  Thus q0 in the NFA-epsilon becomes {q0,q1,q2} because the machine can move
  from q0 to q1 by an epsilon move, then check q1 and find that it can move
  from q1 to q2 by an epsilon move.

  q1 in the NFA-epsilon becomes {q1,q2} because the machine can move from
  q1 to q2 by an epsilon move.

  q2 in the NFA-epsilon becomes {q2} just to keep the notation the same. q2
  can go nowhere except q2, that is what phi means, on an epsilon move.
  We do not show the epsilon transition of a state to itself here, but,
  beware, we will take into account the state to itself epsilon transition
  when converting NFA's to regular expressions.

  The initial state of our new machine is {q0,q1,q2} the epsilon closure of q0

  The final state(s) of our new machine is the new state(s) that contain
  a state symbol that was a final state in the original machine.

  The new machine accepts the same language as the old machine, thus same sigma.

  So far we have for out new NFA
  Q' = { {q0,q1,q2}, {q1,q2}, {q2} } or renamed  { qx, qy, qz }
  sigma = { a, b, c }
  F' = { {q0,q1,q2}, {q1,q2}, {q2} } or renamed  { qx, qy, qz }
  q0 = {q0,q1,q2}                    or renamed  qx

                                        inputs

   delta'            |      a       |      b       |      c   
         ------------+--------------+--------------+--------------
   qx or  {q0,q1,q2} |              |              |
         ------------+--------------+--------------+--------------
   qy or  {q1,q2}    |              |              |  
         ------------+--------------+--------------+--------------
   qz or  {q2}       |              |              |  
         ------------+--------------+--------------+--------------

  Now we fill in the transitions. Remember that a NFA has transition entries
  that are sets. Further, the names in the transition entry sets must be
  only the state names from Q'.

  Very carefully consider each old machine transitions in the first row.
  You can ignore any "phi" entries and ignore the "epsilon" column.
  In the old machine  delta(q0,a)=q0 thus in the new machine
  delta'({q0,q1,q2},a)={q0,q1,q2} this is just because the new machine
  accepts the same language as the old machine and must at least have the
  the same transitions for the new state names.

                                         inputs

   delta'            |      a       |       b      |       c   
         ------------+--------------+--------------+--------------
   qx or  {q0,q1,q2} | {{q0,q1,q2}} |              |
         ------------+--------------+--------------+--------------
   qy or  {q1,q2}    |              |              |  
         ------------+--------------+--------------+--------------
   qz or  {q2}       |              |              |  
         ------------+--------------+--------------+--------------

  No more entries go under input a in the first row because
  old delta(q1,a)=phi, delta(q2,a)=phi

  Now consider the input b in the first row, delta(q0,b)=phi, delta(q1,b)={q2}
  and delta(q2,b)=phi. The reason we considered q0, q1 and q2 in the old
  machine was because out new state has symbols q0, q1 and q2 in the new
  state name from the epsilon closure. Since q1 is in {q0,q1,q2} and
  delta(q1,b)=q1 then delta'({q0,q1,q2},b)={q1,q2}. WHY {q1,q2} ?, because
  {q1,q2} is the new machines name for the old machines name q1. Just
  compare the zeroth column of delta to delta'. So we have


                                         inputs

   delta'            |      a       |       b      |       c   
         ------------+--------------+--------------+--------------
   qx or  {q0,q1,q2} | {{q0,q1,q2}} | {{q1,q2}}    |
         ------------+--------------+--------------+--------------
   qy or  {q1,q2}    |              |              |  
         ------------+--------------+--------------+--------------
   qz or  {q2}       |              |              |  
         ------------+--------------+--------------+--------------

  Now, because our new qx state has a symbol q2 in its name and
  delta(q2,c)=q2 is in the old machine, the new name for the old q2,
  which is qz or {q2} is put into the input c transition in row 1.


                                         inputs

   delta'            |      a       |       b      |       c   
         ------------+--------------+--------------+--------------
   qx or  {q0,q1,q2} | {{q0,q1,q2}} | {{q1,q2}}    | {{q2}}  or qz
         ------------+--------------+--------------+--------------
   qy or  {q1,q2}    |              |              |  
         ------------+--------------+--------------+--------------
   qz or  {q2}       |              |              |  
         ------------+--------------+--------------+--------------

  Now, tediously, move on to row two, ... .
  You are considering all transitions in the old machine, delta,
  for all old machine state symbols in the name of the new machines states.
  Fine the old machine state that results from an input and translate
  the old machine state to the corresponding new machine state name and
  put the new machine state name in the set in delta'. Below are the
  "long new state names" and the renamed state names in delta'.


                                         inputs

   delta'            |      a       |       b      |       c   
         ------------+--------------+--------------+--------------
   qx or  {q0,q1,q2} | {{q0,q1,q2}} | {{q1,q2}}    | {{q2}}  or {qz}
         ------------+--------------+--------------+--------------
   qy or  {q1,q2}    | phi          | {{q1,q2}}    | {{q2}}  or {qz}
         ------------+--------------+--------------+--------------
   qz or  {q2}       | phi          | phi          | {{q2}}  or {qz}
         ------------+--------------+--------------+--------------


                    inputs

   delta'   |  a   |  b   |  c      <-- input alphabet sigma   
         ---+------+------+-----
     /   qx | {qx} | {qy} | {qz}
    /    ---+------+------+-----
  Q'     qy | phi  | {qy} | {qz}
   \     ---+------+------+-----
    \    qz | phi  | phi  | {qz}  
         ---+------+------+-----

  The figure above labeled NFA shows this state transition table.

  It seems rather trivial to add the column for epsilon transitions,
  but we will make good use of this in converting regular expressions
  to machines. regular-expression  ->  NFA-epsilon  ->  NFA  ->  DFA.

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