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Courtesy Costas Busch - RPI1 Turing’s Thesis. Courtesy Costas Busch - RPI2 Turing’s thesis: Any computation carried out by mechanical means can be performed.

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Presentation on theme: "Courtesy Costas Busch - RPI1 Turing’s Thesis. Courtesy Costas Busch - RPI2 Turing’s thesis: Any computation carried out by mechanical means can be performed."— Presentation transcript:

1 Courtesy Costas Busch - RPI1 Turing’s Thesis

2 Courtesy Costas Busch - RPI2 Turing’s thesis: Any computation carried out by mechanical means can be performed by a Turing Machine (1930)

3 Courtesy Costas Busch - RPI3 Computer Science Law: A computation is mechanical if and only if it can be performed by a Turing Machine There is no known model of computation more powerful than Turing Machines

4 Courtesy Costas Busch - RPI4 Definition of Algorithm: An algorithm for function is a Turing Machine which computes

5 Courtesy Costas Busch - RPI5 When we say: There exists an algorithm Algorithms are Turing Machines We mean: There exists a Turing Machine that executes the algorithm

6 Courtesy Costas Busch - RPI6 Variations of the Turing Machine

7 Courtesy Costas Busch - RPI7 Read-Write Head Control Unit Deterministic The Standard Model Infinite Tape (Left or Right)

8 Courtesy Costas Busch - RPI8 Variations of the Standard Model Stay-Option Semi-Infinite Tape Off-Line Multitape Multidimensional Nondeterministic Turing machines with:

9 Courtesy Costas Busch - RPI9 We want to prove: Each Class has the same power with the Standard Model The variations form different Turing Machine Classes

10 Courtesy Costas Busch - RPI10 Same Power of two classes means: Both classes of Turing machines accept the same languages

11 Courtesy Costas Busch - RPI11 Same Power of two classes means: For any machine of first class there is a machine of second class such that: And vice-versa

12 Courtesy Costas Busch - RPI12 a technique to prove same powerSimulation: Simulate the machine of one class with a machine of the other class First Class Original Machine Second Class Simulation Machine

13 Courtesy Costas Busch - RPI13 Configurations in the Original Machine correspond to configurations in the Simulation Machine Original Machine: Simulation Machine:

14 Courtesy Costas Busch - RPI14 The Simulation Machine and the Original Machine accept the same language Original Machine: Simulation Machine: Final Configuration

15 Courtesy Costas Busch - RPI15 Turing Machines with Stay-Option The head can stay in the same position Left, Right, Stay L,R,S: moves

16 Courtesy Costas Busch - RPI16 Example: Time 1 Time 2

17 Courtesy Costas Busch - RPI17 Stay-Option Machines have the same power with Standard Turing machines Theorem:

18 Courtesy Costas Busch - RPI18 Proof: Part 1: Stay-Option Machines are at least as powerful as Standard machines Proof:a Standard machine is also a Stay-Option machine (that never uses the S move)

19 Courtesy Costas Busch - RPI19 Part 2: Standard Machines are at least as powerful as Stay-Option machines Proof:a standard machine can simulate a Stay-Option machine Proof:

20 Courtesy Costas Busch - RPI20 Stay-Option Machine Simulation in Standard Machine Similar for Right moves

21 Courtesy Costas Busch - RPI21 Stay-Option Machine Simulation in Standard Machine For every symbol

22 Courtesy Costas Busch - RPI22 Example Stay-Option Machine: 12 Simulation in Standard Machine: 123

23 Courtesy Costas Busch - RPI23 Standard Machine--Multiple Track Tape track 1 track 2 one symbol

24 Courtesy Costas Busch - RPI24 track 1 track 2 track 1 track 2

25 Courtesy Costas Busch - RPI25 Semi-Infinite Tape.........

26 Courtesy Costas Busch - RPI26 Standard Turing machines simulate Semi-infinite tape machines: Trivial

27 Courtesy Costas Busch - RPI27 Semi-infinite tape machines simulate Standard Turing machines: Standard machine......... Semi-infinite tape machine.........

28 Courtesy Costas Busch - RPI28 Standard machine......... Semi-infinite tape machine with two tracks......... reference point Right part Left part

29 Courtesy Costas Busch - RPI29 Left partRight part Standard machine Semi-infinite tape machine

30 Courtesy Costas Busch - RPI30 Standard machine Semi-infinite tape machine Left part Right part For all symbols

31 Courtesy Costas Busch - RPI31 Standard machine......... Semi-infinite tape machine Right part Left part Time 1

32 Courtesy Costas Busch - RPI32 Time 2 Right part Left part Standard machine......... Semi-infinite tape machine

33 Courtesy Costas Busch - RPI33 Semi-infinite tape machine Left part At the border: Right part

34 Courtesy Costas Busch - RPI34......... Semi-infinite tape machine Right part Left part......... Right part Left part Time 1 Time 2

35 Courtesy Costas Busch - RPI35 Theorem:Semi-infinite tape machines have the same power with Standard Turing machines

36 Courtesy Costas Busch - RPI36 The Off-Line Machine Control Unit Input File Tape read-only read-write

37 Courtesy Costas Busch - RPI37 Off-line machines simulate Standard Turing Machines: Off-line machine: 1. Copy input file to tape 2. Continue computation as in Standard Turing machine

38 Courtesy Costas Busch - RPI38 1. Copy input file to tape Input File Tape Standard machine Off-line machine

39 Courtesy Costas Busch - RPI39 2. Do computations as in Turing machine Input File Tape Standard machine Off-line machine

40 Courtesy Costas Busch - RPI40 Standard Turing machines simulate Off-line machines: Use a Standard machine with four track tape to keep track of the Off-line input file and tape contents

41 Courtesy Costas Busch - RPI41 Input File Tape Off-line Machine Four track tape -- Standard Machine Input File head position Tape head position

42 Courtesy Costas Busch - RPI42 Input File head position Tape head position Repeat for each state transition: Return to reference point Find current input file symbol Find current tape symbol Make transition Reference point

43 Courtesy Costas Busch - RPI43 Off-line machines have the same power with Standard machines Theorem:

44 Courtesy Costas Busch - RPI44 Multitape Turing Machines Control unit Tape 1Tape 2 Input

45 Courtesy Costas Busch - RPI45 Time 1 Time 2 Tape 1Tape 2

46 Courtesy Costas Busch - RPI46 Multitape machines simulate Standard Machines: Use just one tape

47 Courtesy Costas Busch - RPI47 Standard machines simulate Multitape machines: Use a multi-track tape A tape of the Multiple tape machine corresponds to a pair of tracks Standard machine:

48 Courtesy Costas Busch - RPI48 Multitape Machine Tape 1Tape 2 Standard machine with four track tape Tape 1 head position Tape 2 head position

49 Courtesy Costas Busch - RPI49 Repeat for each state transition: Return to reference point Find current symbol in Tape 1 Find current symbol in Tape 2 Make transition Tape 1 head position Tape 2 head position Reference point

50 Courtesy Costas Busch - RPI50 Theorem:Multi-tape machines have the same power with Standard Turing Machines

51 Courtesy Costas Busch - RPI51 Same power doesn’t imply same speed: Language Acceptance Time Standard machine Two-tape machine

52 Courtesy Costas Busch - RPI52 Standard machine: Go back and forth times Two-tape machine: Copy to tape 2 Leave on tape 1 Compare tape 1 and tape 2 ( steps)

53 Courtesy Costas Busch - RPI53 MultiDimensional Turing Machines Two-dimensional tape HEAD Position: +2, -1 MOVES: L,R,U,D U: up D: down

54 Courtesy Costas Busch - RPI54 Multidimensional machines simulate Standard machines: Use one dimension

55 Courtesy Costas Busch - RPI55 Standard machines simulate Multidimensional machines: Standard machine: Use a two track tape Store symbols in track 1 Store coordinates in track 2

56 Courtesy Costas Busch - RPI56 symbols coordinates Two-dimensional machine Standard Machine

57 Courtesy Costas Busch - RPI57 Repeat for each transition Update current symbol Compute coordinates of next position Go to new position Standard machine:

58 Courtesy Costas Busch - RPI58 MultiDimensional Machines have the same power with Standard Turing Machines Theorem:

59 Courtesy Costas Busch - RPI59 NonDeterministic Turing Machines Non Deterministic Choice

60 Courtesy Costas Busch - RPI60 Time 0 Time 1 Choice 1 Choice 2

61 Courtesy Costas Busch - RPI61 Input string is accepted if this a possible computation Initial configurationFinal Configuration Final state

62 Courtesy Costas Busch - RPI62 NonDeterministic Machines simulate Standard (deterministic) Machines: Every deterministic machine is also a nondeterministic machine

63 Courtesy Costas Busch - RPI63 Deterministic machines simulate NonDeterministic machines: Keeps track of all possible computations Deterministic machine:

64 Courtesy Costas Busch - RPI64 Non-Deterministic Choices Computation 1

65 Courtesy Costas Busch - RPI65 Non-Deterministic Choices Computation 2

66 Courtesy Costas Busch - RPI66 Keeps track of all possible computations Deterministic machine: Simulation Stores computations in a two-dimensional tape

67 Courtesy Costas Busch - RPI67 Time 0 NonDeterministic machine Deterministic machine Computation 1

68 Courtesy Costas Busch - RPI68 Computation 1 Choice 1 Choice 2 Computation 2 NonDeterministic machine Deterministic machine Time 1

69 Courtesy Costas Busch - RPI69 Repeat Execute a step in each computation: If there are two or more choices in current computation: 1. Replicate configuration 2. Change the state in the replica

70 Courtesy Costas Busch - RPI70 Theorem: NonDeterministic Machines have the same power with Deterministic machines

71 Courtesy Costas Busch - RPI71 Remark: The simulation in the Deterministic machine takes exponential time compared to the NonDeterministic machine

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