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1 Recap lecture 21 Example of Moore machine, Mealy machine, Examples, complementing machine, Incrementing machine.

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Presentation on theme: "1 Recap lecture 21 Example of Moore machine, Mealy machine, Examples, complementing machine, Incrementing machine."— Presentation transcript:

1 1 Recap lecture 21 Example of Moore machine, Mealy machine, Examples, complementing machine, Incrementing machine.

2 2 Solution of the Task Incrementing machine with two states 0/1 q1q1 q0q0 1/0 0/0, 1/1

3 3 Applications of Incrementing and Complementing machines 1’s complementing and incrementing machines which are basically Mealy machines are very much helpful in computing. The incrementing machine helps in building a machine that can perform the addition of binary numbers. Using the complementing machine along with incrementing machine, one can build a machine that can perform the subtraction of binary numbers, as shown in the following method

4 4 Subtracting a binary number from another Method: To subtract a binary b from a binary number a 1.Add 1’s complement of b to a (ignoring the overflow, if any) 2.Increase the result, in magnitude, by 1 (use the incrementing machine ). Ignoring the overflow if any. Note: If there is no overflow in (1). Take 1’s complement once again in (2), instead. This situation occurs when b is greater than a, in magnitude. Following is an example of subtraction of binary numbers

5 5 Example To subtract the binary number 101 from the binary number 1110, let a = 1110 and b = 101 = 0101. (Here the number of digits of b are equated with that of a) i)Adding 1’s complement (1010) of b to a. 1110 +1010 11000 which gives 1000 ( ignoring the overflow)

6 6 Example continued … ii)Using the incrementing machine, increase the above result 1000, in magnitude, by 1 1000 +1 1001 which is the same as obtained by ordinary subtraction.

7 7 Note It may be noted that the above method of subtraction of binary numbers may be applied to subtraction of decimal numbers with the change that 9’s complement of b will be added to a, instead in step (1). Following is the task in this regard

8 8 Task Subtract 39 from 64 Solution:Taking a=64 and b=39. i)Adding 9’s complement (60) of b to a. 64 +60 124 which gives 24 ( ignoring the overflow) ii)Increasing the above result 24, in magnitude, by 124 +1 25 which is the same as obtained by ordinary subtraction.

9 9 Equivalent machines Two machines are said to be equivalent if they print the same output string when the same input string is run on them. Remark: Two Moore machines may be equivalent. Similarly two Mealy machines may also be equivalent, but a Moore machine can’t be equivalent to any Mealy machine. However, ignoring the extra character printed by the Moore machine, there exists a Mealy machine which is equivalent to the Moore machine.

10 10 Theorem Statement: For every Moore machine there is a Mealy machine that is equivalent to it (ignoring the extra character printed by the Moore machine). Proof: Let M be a Moore machine, then shifting the output characters corresponding to each state to the labels of corresponding incoming transitions, machine thus obtained will be a Mealy machine equivalent to M. Following is a note

11 11 Note It may be noted that while converting a Moore machine into an equivalent Mealy machine, the output character of a state will be ignored if there is no incoming transition at that state. A loop at a state is also supposed to be an incoming transition. Following is the example of converting a Moore machine into an equivalent Mealy machine

12 12 Example Consider the following Moore machine Using the method described earlier, the above machine may be equivalent to the following Mealy machine b a q 0 /0 a b q 1 /1 q 2 /0 q 3 /1 a,b a b

13 13 Example continued... b/0 a/1 q0q0 b /1 q1q1 q2q2 q3q3 a /1,b /1 a /0 b /0 Running the string abbabbba on both the machines, the output string can be determined by the following table

14 14 Example continued... 111111010Moore q3q3 q3q3 q3q3 q3q3 q3q3 q3q3 q2q2 q1q1 q0q0 States abbbabbaInput 11111101Mealy

15 15 Theorem Statement: For every Mealy machine there is a Moore machine that is equivalent to it (ignoring the extra character printed the Moore machine). Proof: Let M be a Mealy machine. At each state there are two possibilities for incoming transitions 1.The incoming transitions have the same output character. 2.The incoming transitions have different output characters.

16 16 Proof continued … If all the transitions have same output characters, then shift that character to the corresponding state. If all the transitions have different output characters, then the state will be converted to as many states as the number of different output characters for these transitions, which shows that if this happens at state q i then q i will be converted to q i 1 and q i 2 i.e. if at q i there are the transitions with two output characters then q i 1 for one character and q i 2 for other character.

17 17 Proof continued … Shift the output characters of the transitions to the corresponding new states q i 1 and q i 2. Moreover, these new states q i 1 and q i 2 should behave like q i as well. Continuing the process, the machine thus obtained, will be a Moore machine equivalent to Mealy machine M. Following is a note

18 18 Note It may be noted that if there is no incoming transition at certain state then any of the output characters may be associated with that state. It may also be noted that if the initial state is converted into more than one new states then only one of these new states will be considered to be the initial state. Following is an example

19 19 Example Consider the following Mealy machine a/0 b/1 a/1 q1q1 a/0 q2q2 q0q0 q3q3 a/1 b/0 b/1

20 20 Example continued... a/0 b a/1 q1q1 a/0 q2q2 q 0 /1 q3q3 a/1 b/0 b/1 Shifting the output character 1 of transition b to q 0

21 21 Example continued... a b a/1 q 1 /0 a/0 q2q2 q 0 /1 q3q3 a/1 b/0 b/1 Shifting the output character 0 of transition a to q 1

22 22 Example continued... a b a/1 q 1 /0 a/0 q 2 /1 q 0 /1 q3q3 a/1 b/0 b/1 b Shifting the output character 1 of transition b to q 2

23 23 Example continued... a q 1 /0 q 2 /1 q 0 /1 q 3 /0 b q 3 /1 a a b b b b a 1 2 a Splitting q 3 into q 3 and q 3 12

24 24 Example continued … Running the string abbabbba on both the machines, the output strings can be determined by the following table 01011110Mealy q1q1 q0q0 q3q3 q0q0 q3q3 q3q3 q2q2 q1q1 q0q0 States abbbabbaInput 010111101Moore

25 25 Summing Up Applications of complementing and incrementing machines, Equivalent machines, Moore equivalent to Mealy, proof, example, Mealy equivalent to Moore, proof, example

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