Concatenation of FAs

<< Kleeneâ€™s Theorem Part III

Closure of an FA >>

Theory of Automata

(CS402)

Theory of Automata

Lecture N0. 13

Reading Material

Chapter 7

Introduction to Computer Theory

Summary

Examples of Kleene's theorem part III (method 1) continued, Kleene's theorem part III (method 2:

Concatenation of FAs), Example of Kleene's theorem part III (method 2 : Concatenation of FAs)

Note

It may be noted that the example discussed at the end of previous lecture, FA1 contains two states while FA2

contains three states. Hence the total number of possible combinations of states of FA1 and FA2, in sequence,

will be six. For each combination the transitions for both a and b can be determined, but using the method in the

example, number of states of FA3 was reduced to five.

Example

Let r1 = (a+b)*a and the corresponding FA1 be

x1-

x2+

also r2 = (a+b)((a+b)(a+b))* or ((a+b)(a+b))*(a+b) and FA2 be

a,b

y1-

y2+

a,b

FA corresponding to r1+r2 can be determined as

a,b

x1-

y1-

x2+

y2+

a,b

New States after reading

Old States

z1-∫(x1,y1)

(x2,y2) ∫z2

(x1,y2) ∫ z3

z2+∫(x2,y2)

(x2,y1) ∫z4

(x1,y1) ∫ z1

z3+ ∫(x1,y2)

(x2,y1) ∫z4

(x1,y1) ∫ z1

z4+ ∫(x2,y1)

(x2,y2) ∫ z2

(x1,y2) ∫ z3

z2+

z1-

z4+

z3+

Example

Let r1 = ((a+b)(a+b))* and the corresponding FA1 be

a,b

x1±

a,b

Theory of Automata

(CS402)

also r2 = (a+b)((a+b)(a+b))* or ((a+b)(a+b))*(a+b) and FA2 be

a,b

y1-

y2+

a,b

FA corresponding to r1+r2 can be determined as

New States after reading

Old States

z1±∫(x1,y1)

(x2,y2) ∫z2

(x2,y2) ∫ z2

(x1,y1) ∫z1

(x1,y1) ∫ z1

z2+∫(x2,y2)

Hence the required FA will be as follows

a,b

z1±

z2+

a,b

Method2 (Concatenation of two FAs):

Using the FAs corresponding to r1 and r2, an FA can be built, corresponding to r1r2. This method can be

developed considering the following examples

Example

Let r1 = (a+b)*b defines L1 and FA1 be

x1-

x2+

and r2 = (a+b ) aa (a+b ) defines L2 and FA2 be

a,b

y3+

y1-

Let FA3 be an FA corresponding to r1r2, then the initial state of FA3 must correspond to the initial state of FA1

and the final state of FA3 must correspond to the final state of FA2.Since the language corresponding to r1r2 is

the concatenation of corresponding languages L1 and L2, consists of the strings obtained, concatenating the

strings of L1 to those of L2 , therefore the moment a final state of first FA is entered, the possibility of the

initial state of second FA will be included as well.

Since, in general, FA3 will be different from both FA1 and FA2, so the labels of the states of FA3 may be

supposed to be z1,z2, z3, ..., where z1 stands for the initial state. Since z1 corresponds to the states x1, so there

will be two transitions separately for each letter read at z1. It will give two possibilities of states which

correspond to either z1 or different from z1. This process may be expressed in the following transition table for

all possible states of FA3

x1-

x2+

a,b

y3+

y1-

Theory of Automata

(CS402)

New States after reading

Old States

x1∫z1

(x2,y1)∫ z2

z1-∫x1

z2∫(x2,y1)

(x1,y2)∫z3

(x2,y1)∫ z2

z3∫(x1,y2)

(x1,y3)∫z4

(x2,y1)∫ z2

z4+∫(x1,y3)

(x1,y3)∫ z4

(x2,y1,y3)∫ z5

z5+∫(x2,y1,y3)

(x1,y2 ,y3)∫ z6

(x2,y1,y3)∫ z5

z6+∫(x1,y2,y3)

(x1,y3)∫ z4

(x2 ,y1,y3)∫ z5

Hence the required FA will be as follows

z4+

z1-

z5+

z6+

Note: Another example is discussed in the next lecture.

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