Presentation is loading. Please wait.

Presentation is loading. Please wait.

COSC 3340: Introduction to Theory of Computation

Published byAdam Park Modified over 5 years ago

Similar presentations

Presentation on theme: "COSC 3340: Introduction to Theory of Computation"— Presentation transcript:

1 COSC 3340: Introduction to Theory of Computation
University of Houston Dr. Verma Lecture 4 Lecture 4 UofH - COSC Dr. Verma

2 Formal definition of NFA acceptance
Define *(q, w) as a set of states: p ε *(q, w) if there is a directed path from q to p labeled w Example: consider NFA of Lecture 3 *(q0, 1) = ? Ans: {q0, q1} *(q0, 11) = ? Ans: {q0, q1, q2} Lecture 4 UofH - COSC Dr. Verma

3 NFA acceptance (contd.)
w is accepted by NFA M iff *(q0, w)  F is nonempty. L(M) = {w in * | w is accepted by M}. Lecture 4 UofH - COSC Dr. Verma

4 NFA vs. DFA Is NFA more powerful than DFA? Theorem: Proof Idea:
Ans: No. Theorem: For every NFA M there is an equivalent DFA M' Proof Idea: NFA is in a set of states at any point during reading a string. DFA will use a lot of states to keep track of this. Important Assumption: No transition labeled by epsilon. (Will get rid of this assumption later.) Lecture 4 UofH - COSC Dr. Verma

5 Equivalent DFA construction.
NFA M = (Q, , , s, F) DFA M' = (Q', , , s', F') where: Q' = 2Q s' = {s} F' = {P | P  F is nonempty} ({p1, p2, pm}, ) = *(p1, )  *(p2, )  ...  *(pm, ) i.e. find all the states that can be reached on  from all the NFA states in a DFA state. Lecture 4 UofH - COSC Dr. Verma

6 Example: Equivalent DFA construction
NFA Lecture 4 UofH - COSC Dr. Verma

7 Equivalent DFA construction (contd.)
Lecture 4 UofH - COSC Dr. Verma

8 How to handle epsilon transitions?
Define e-closure of state q as *(q, ). notation: e-closure(q). Example: Lecture 4 UofH - COSC Dr. Verma

9 Handling epsilon transitions (contd.)
Extend e-closure to sets of states by: e-closure({s1, ... , sm}) = e-closure(s1)  ...  e-closure(sm) Now let s' = e-closure({s}). and, ({p1,..., pm}, ) = e-closure(*(p1, ))  ...  e-closure(*(pm, )) to complete construction of DFA. Lecture 4 UofH - COSC Dr. Verma

10 Example: Handling epsilon transitions.
Lecture 4 UofH - COSC Dr. Verma

11 DFA = ? Lecture 4 UofH - COSC Dr. Verma

12 Language Operations Concatenation. Notation: LL' or just LL'
L  L' = {uv | u in L, v in L'}. Kleene Star. Notation: L* L* = { w in * | w = w1...wk for some k >= 0 and each wi in L}. Examples: if L = {a(2n+1) | n >= 0}. L' = {b(2n) | n > = 0}. LL' = ? Ans: LL' = {a(2n+1) b(2m) | n, m > = 0} L* = ? Ans: {an | n >= 0} U, ., * are called regular operations. Lecture 4 UofH - COSC Dr. Verma

13 Closure properties of regular languages.
Previously we saw closure under  and . New: Regular languages are closed under Concatenation Kleene star Complement. Lecture 4 UofH - COSC Dr. Verma

14 L = {w in {a,b}* | w has even a’s }
Examples L = {w in {a,b}* | w has even a’s } Lecture 4 UofH - COSC Dr. Verma

15 Examples L' = {w in {a,b}* | w has at least one b} Lecture 4
UofH - COSC Dr. Verma

16 Construction for LL' L’’ = (K,,,s,F) K = K1  K2 s = s1 F = F2  = 1  2  F1 X {e} X {s2} Lecture 4 UofH - COSC Dr. Verma

17 L* and L'* L* M = (K, , , s, F) K = {s}  K1 F = {s}  F1  = 1  F1 X {e} X {s1}  {(s, e, s1)} Given M1 = (K1, , 1, s1, F1) L’* Lecture 4 UofH - COSC Dr. Verma

18 Complement of L and L' Complement of L Complement of L’ Lecture 4
UofH - COSC Dr. Verma

19 General Construction for Complement
DFA M = (K, , δ, s, F) K = K1 s = s1 F = K - F1 δ = δ1 L(M) = Complement of L(M1) DFA M1 = (K1, , δ1, s1, F1) Exercise: Will this construction work for NFAs? Explain your answer. Lecture 4 UofH - COSC Dr. Verma

Download ppt "COSC 3340: Introduction to Theory of Computation"

Similar presentations

CSC 361NFA vs. DFA1. CSC 361NFA vs. DFA2 NFAs vs. DFAs NFAs can be constructed from DFAs using transitions: Called NFA- Suppose M 1 accepts L 1, M 2 accepts.

CSC 361NFA vs. DFA1. CSC 361NFA vs. DFA2 NFAs vs. DFAs NFAs can be constructed from DFAs using transitions: Called NFA- Suppose M 1 accepts L 1, M 2 accepts.
Lecture 8 From NFA to Regular Language. Induction on k= # of states other than initial and final states K=0 a a* b a c d c*a(d+bc*a)*

Lecture 8 From NFA to Regular Language. Induction on k= # of states other than initial and final states K=0 a a* b a c d c*a(d+bc*a)*
Lecture 3UofH - COSC 3340 - Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 3.

Lecture 3UofH - COSC Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 3.
Costas Busch - RPI1 Single Final State for NFAs. Costas Busch - RPI2 Any NFA can be converted to an equivalent NFA with a single final state.

Costas Busch - RPI1 Single Final State for NFAs. Costas Busch - RPI2 Any NFA can be converted to an equivalent NFA with a single final state.
CS 310 – Fall 2006 Pacific University CS310 Converting NFA to DFA Sections:1.2 Page 54 September 15, 2006.

CS 310 – Fall 2006 Pacific University CS310 Converting NFA to DFA Sections:1.2 Page 54 September 15, 2006.
1 Module 21 Closure Properties for LFSA using NFA’s –From now on, when I say NFA, I mean any NFA including an NFA- unless I add a specific restriction.

1 Module 21 Closure Properties for LFSA using NFA’s –From now on, when I say NFA, I mean any NFA including an NFA- unless I add a specific restriction.
Transparency No. 4-1 Formal Language and Automata Theory Chapter 4 Patterns, Regular Expressions and Finite Automata (include lecture 7,8,9) Transparency.

Transparency No. 4-1 Formal Language and Automata Theory Chapter 4 Patterns, Regular Expressions and Finite Automata (include lecture 7,8,9) Transparency.
1 Regular Expressions. 2 Regular expressions describe regular languages Example: describes the language.

1 Regular Expressions. 2 Regular expressions describe regular languages Example: describes the language.
Introduction to the Theory of Computation John Paxton Montana State University Summer 2003.

Introduction to the Theory of Computation John Paxton Montana State University Summer 2003.
Fall 2004COMP 3351 Single Final State for NFA. Fall 2004COMP 3352 Any NFA can be converted to an equivalent NFA with a single final state.

Fall 2004COMP 3351 Single Final State for NFA. Fall 2004COMP 3352 Any NFA can be converted to an equivalent NFA with a single final state.
1 Single Final State for NFAs and DFAs. 2 Observation Any Finite Automaton (NFA or DFA) can be converted to an equivalent NFA with a single final state.

1 Single Final State for NFAs and DFAs. 2 Observation Any Finite Automaton (NFA or DFA) can be converted to an equivalent NFA with a single final state.
Lecture 7 Sept 22, 2011 Goals: closure properties regular expressions.

Lecture 7 Sept 22, 2011 Goals: closure properties regular expressions.
Fall 2006Costas Busch - RPI1 Properties of Regular Languages.

Fall 2006Costas Busch - RPI1 Properties of Regular Languages.
Lecture 3 Goals: Formal definition of NFA, acceptance of a string by an NFA, computation tree associated with a string. Algorithm to convert an NFA to.

Lecture 3 Goals: Formal definition of NFA, acceptance of a string by an NFA, computation tree associated with a string. Algorithm to convert an NFA to.
1 Lecture 19 Closure Properties for LFSA using NFA’s –union second proof –concatenation –Kleene closure.

1 Lecture 19 Closure Properties for LFSA using NFA’s –union second proof –concatenation –Kleene closure.
CS5371 Theory of Computation Lecture 4: Automata Theory II (DFA = NFA, Regular Language)

CS5371 Theory of Computation Lecture 4: Automata Theory II (DFA = NFA, Regular Language)
1 Non-Deterministic Automata Regular Expressions.

1 Non-Deterministic Automata Regular Expressions.
Lecture 7UofH - COSC 3340 - Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 7.

Lecture 7UofH - COSC Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 7.
Lecture 27UofH - COSC 3340 - Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 27.

Lecture 27UofH - COSC Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 27.
Lecture 5UofH - COSC 3340 - Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 5.

Lecture 5UofH - COSC Dr. Verma 1 COSC 3340: Introduction to Theory of Computation University of Houston Dr. Verma Lecture 5.

Similar presentations

Ads by Google