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Turing Machines. Hopcroft, Motawi, Ullman, Chap 8. Models of computation. Finite automata and regular expressions Represent regular languages Can’t “count” Grammars and pushdown automata Represent context free languages Can count and remember symbols once Turing machines - PowerPoint PPT Presentation
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Turing Machines
Hopcroft, Motawi, Ullman,Chap 8
Models of computation Finite automata and regular expressions
Represent regular languages Can’t “count”
Grammars and pushdown automata Represent context free languages Can count and remember symbols once
Turing machines Represent recursive languages Models contemporary programs
Turing Machine Model Input tape surrounded by infinitely
many blanks Tape head can move back and
forth the tape and replace current symbol
TM
BBBBBBB000111BBBBB… …
TM definition A Turing Machine M is a tuple
M = (Q, , , , q0, B, F), where: Q is a set of states is the input alphabet is the tape alphabet = {B} other tape symbols : Q Q D is the state transition function
mapping (state, symbol) to (state, symbol, direction);D = {,}; may be undefined for some pairs
q0 is the start state of M B is the blank symbol (default symbol on input tape) F Q is the set of accepting states or final states of M
(if applicable)
TM that accepts 0n1n
Q={q0,q1 ,q2,q3,q4}, ={0,1}, ={0,1,B,Y} defined as follows:
(q0,0) = (q1,B,) erase leftmost 0 (q1,0) = (q1,0,) move to right until a 1
(q1,Y) = (q1,Y,) is encountered, replace(q1,1) = (q2,Y,) that 1 with Y
(q2,Y) = (q2,Y,) move to left until a blank(q2,0) = (q2,0,) is encountered, then go(q2,B) = (q0,B,) back to initial state
(q0,Y) = (q3,Y,) if Y on tape go to state 3 (q3,Y) = (q3,Y,) ensure only Y’s remain on tape
(q3,B) = (q4,B,) accept once B is seen (F={q4})
TM that increments a bit-string Q={q0,q1 ,q2,q3}, ={0,1}, ={0,1,B,X} defined as follows:
(q0,0) = (q0,0,) go to rightmost(q0,1) = (q0,1,) non-blank(q0,B) = (q1,B,)
(q1,1) = (q1,0,) replace 1’s with 0’s(q1,0) = (q2,1,) until 0/B is encountered, (q1,B) = (q2,1,) replace that 0/B with a 1
No applicable transitions from q2 means the turing machine halts
Instantaneous descriptions Instantaneous description (ID): depicts the
characteristics of the machine as transitions are carried out
For finite automata, the state of the machine and the remaining input is sufficient
For TM’s, the following are needed for an ID: State Symbols on the tape Position of the tape head
Can be expressed as X1X2…Xi-1qXiXi+1…Xnwhich means the TM is in state q, the tape contains X1X2…Xn and the tape head is at Xi
ID example Suppose for the first TM example,
the input is 0011 The initial ID is q00011
After applying the transition(q0,0) = (q1,B,), ID: q1011
Depict this as a move: q00011 | q1011 Next 3 transitions:
(q1,0) = (q1,0,), ID: 0q111(q1,1) = (q2,Y,), ID: q20Y1(q2,0) = (q2,0,), ID: q2B0Y1
Eventually, ID will be YYBq4 (TM accepts)
TM as recognizer A TM accepts a string w if there exists a
sequence of moves fromID q0w to ID uqfv (u,v *, qf F) q0w |* uqfv In the previous example, q00011 |* YYBq4
Given a TM M, L(M) is the set of all strings that M accepts
A language recognized by a TM is called a recursively enumerable language
TM halting on input TMs are also useful for computation In this case, what is important is the
machine halts on input w (and leaves the appropriate output on the tape)
A TM halts on input w if there exists a sequence of moves fromID q0w to ID uqixv (u,v*, x, qiQ)& (qi,x) is undefined (no transition applies) The TM can be viewed as a function; f(w) = uxv
About TMs Church-Turing Thesis: TMs represent what
can be solved by a computer program(a mathematically unprovable statement)
Some problems cannot be solved by a TM (e.g., the Halting Problem)
TMs can be deterministic or nondeterministic; the variation helps in modeling problem complexity classes (P and NP)
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