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Hypercomputation

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Hypercomputation Computing beyond Turing machines Hypercomputation According to the Church Turing thesis, anything that is computable is computable by a Turing machine. – PowerPoint PPT presentation

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Title: Hypercomputation


1
Hypercomputation
  • Computing beyond Turing machines

2
Hypercomputation
  • According to the Church Turing thesis, anything
    that is computable is computable by a Turing
    machine.
  • But how do we really know this? Maybe some
    devices are more powerful. This is the topic of
    hypercomputation.

3
Hypercomputation
  • If some computing device were more powerful than
    a Turing machine, maybe we could solve the
    halting problem and other problems that are
    currently classified as unsolvable.
  • But how might such a device work?

4
Possibilities
  • Compute with infinite precision real numbers
  • Quantum mechanical system using an infinite
    superposition of states (Kieu)
  • A TM that keeps getting smaller and smaller,
    faster and faster
  • None of these seem possible at present

5
But the world is a strange place so it may be
possible someday
  • Wave-particle duality
  • Double slit experiment
  • Schrödinger's cat
  • Kieus algorithm for Hilberts Tenth Problem
  • Faster than light travel or information transfer?
    See this link.

6
Wave Particle Duality
  • In quantum mechanics, the wave-particle duality
    is explained as follows every system and
    particle is described by wave functions which
    encode the probability distributions of all
    measurable variables. The position of the
    particle is one such variable. Before an
    observation is made the position of the particle
    is described in terms of probability waves which
    can interfere with each other.

7
Wave Particle Duality
  • After measurement the position of the particle
    collapses to one location, the probability of
    each location determined by the wave probability
    function.

8
  • In fact according to quantum mechanics the
    physical world is probabilistic and not
    deterministic
  • The future is not completely determined by the
    past
  • Leaves room for free will philosophically
  • Differs from Newtonian mechanics which is
    deterministic
  • Do electrons have free will?

9
Double Slit Experiment
  • A single particle traveling through two slits
    creates interference patterns with itself.

10
Schrödinger's cat
  • Schrödinger's cat is a thought experiment devised
    by Erwin Schrödinger that attempts to illustrate
    the incompleteness of the theory of quantum
    mechanics when going from subatomic to
    macroscopic systems.

11
Schrödinger's cat
  • A cat is placed in a sealed box. Attached to the
    box is an apparatus containing a radioactive
    nucleus and a canister of poison gas. When the
    nucleus decays, it emits a particle that triggers
    the apparatus, which opens the canister and kills
    the cat.

12
  • According to quantum mechanics, the nucleus is
    described as a superposition (mixture) of
    "decayed nucleus" and "undecayed nucleus".
    However, when the box is opened the experimenter
    sees only a "decayed nucleus/dead cat" or a
    "undecayed nucleus/living cat." The question is
    when does the system stop existing as a mixture
    of states and become one or the other?

13
Schrödinger's cat
  • The purpose of the experiment is to illustrate
    that quantum mechanics is incomplete without some
    rules to describe when the wavefunction collapses
    and the cat becomes dead or alive instead of a
    mixture of both.
  • (Why wasnt it Schrödinger's dog?)

14
  • Curiously, all of this has some practical use in
    quantum cryptography. It is possible to send
    light that is in a superposition of states down a
    fiber optic cable. Placing a wiretap in the
    middle of the cable which intercepts and
    retransmits the transmission will collapse the
    wavefunction (in the Copenhagen interpretation,
    "perform an observation") and cause the light to
    fall into one state or another.

15
  • By performing statistical tests on the light
    received at the other end of the cable, one can
    tell whether it remains in the superposition of
    states or has already been observed and
    retransmitted.

16
  • Uncertainty Principle
  • Tunneling
  • Quantum Superposition

17
Quantum Leaps
  • "We dispute the Turing-Church thesis by showing
    that there exist computable functions --
    computable by executing well-defined quantum
    mechanical procedures in a finite manner -- that
    are not Turing-computable," Kieu claims in a
    recent paper on the topic.

18
  • In other words, Kieu claims to have discovered
    uncomputable problems that are actually
    computable with the help of quantum mechanics.

19
Quantum Algorithm for Hilbert's Tenth Problem
(Kieu)
  • We explore in the framework of Quantum
    Computation the notion of Computability, which
    holds a central position in Mathematics and
    Theoretical Computer Science.

20
  • A quantum algorithm for Hilbert's tenth problem,
    which is equivalent to the Turing halting problem
    and is known to be mathematically noncomputable,
    is proposed where quantum continuous variables
    and quantum adiabatic evolution are employed.

21
  • If this algorithm could be physically
    implemented, as much as it is valid in
    principle--that is, if certain hamiltonian and
    its ground state can be physically constructed
    according to the proposal--quantum computability
    would surpass classical computability as
    delimited by the Church-Turing thesis.

22
  • It is thus argued that computability, and with it
    the limits of Mathematics, ought to be determined
    not solely by Mathematics itself but also by
    Physical Principles.

23
The quantum algorithm of Kieu does not solve the
Hilbert's tenth problemBoris Tsirelson
  • Recently T. Kieu 1 claimed a quantum algorithm
    computing some functions beyond the Church-Turing
    class. He notes that "it is in fact widely
    believed that quantum computation cannot offer
    anything new about computability" and claims the
    opposite.

24
  • However, his quantum algorithm does not work,
    which is the point of my short note. I still
    believe that quantum computation leads to new
    complexity but retains the old computability.
  • Who is right, Kieu or Tsirelson?

25
Faster than light travel
  • Yet a group of physicists have performed
    experiments which seem to suggest that FTL
    communication by quantum tunneling is possible.
    They claim to have transmitted Mozart's 40th
    Symphony through a barrier 11.4cm wide at a speed
    of 4.7c. Their interpretation is, of course, very
    controversial.

26
  • Most physicists say this is a quantum effect
    where no information can actually be passed at
    FTL speeds because of the Heisenberg uncertainty
    principle. If the effect is real it is difficult
    to see why it should not be possible to transmit
    signals into the past by placing the apparatus in
    a fast moving frame of reference.

27
  • refW. Heitmann and G. Nimtz, Phys Lett A196,
    154 (1994)A. Enders and G. Nimtz, Phys Rev E48,
    632 (1993).

28
Light Exceeds Its Own Speed Limit, or Does It?
  • In the most striking of the new experiments by
    Lijun Wang of Princeton a pulse of light that
    enters a transparent chamber filled with
    specially prepared cesium gas is pushed to speeds
    of 300 times the normal speed of light. That is
    so fast that, under these peculiar circumstances,
    the main part of the pulse exits the far side of
    the chamber even before it enters at the near
    side.

29
  • It is as if someone looking through a window from
    home were to see a man slip and fall on a patch
    of ice while crossing the street well before
    witnesses on the sidewalk saw the mishap occur--a
    preview of the future.

30
  • Dr. Chiao, whose own research laid some of the
    groundwork for the experiment, added that
    "there's been a lot of controversy" over whether
    the finding means that actual information--like
    the news of an impending accident--could be sent
    faster than c, the velocity of light. But he said
    that he and most other physicists agreed that it
    could not.

31
  • A paper on the second new experiment, by Daniela
    Mugnai, Anedio Ranfagni and Rocco Ruggeri of the
    Italian National Research Council, described what
    appeared to be slightly faster-than-c propagation
    of microwaves through ordinary air, and was
    published in the May 22 issue of Physical Review
    Letters.

32
  • The overall result of Wangs experiment is an
    outgoing wave exactly the same in shape and
    intensity as the incoming wave the outgoing wave
    just leaves early, before the peak of the
    incoming wave even arrives.
  • As most physicists interpret the experiment, it
    is a low-intensity precursor (sometimes called a
    tail, even when it comes first) of the incoming
    wave that clues the cesium chamber to the
    imminent arrival of a pulse.

33
  • Someone who looked only at the beginning and end
    of the experiment would see only a pulse of light
    that somehow jumped forward in time by moving
    faster than c.
  • "The effect is really quite dramatic," Dr.
    Steinberg said. "For a first demonstration, I
    think this is beautiful."

34
  • But it really wouldn't allow anyone to send
    information faster than c, said Peter W. Milonni,
    a physicist at Los Alamos National Laboratory.
  • "The information is already there in the leading
    edge of the pulse," Dr. Milonni said. "You can
    get the impression of sending information
    superluminally even though you're not sending
    information."

35
  • Not all physicists agree that the question has
    been settled, though. "This problem is still
    open," said Dr. Ranfagni of the Italian group,
    which used an ingenious set of reflecting optics
    to create microwave pulses that seemed to travel
    as much as 25 faster than c over short
    distances.

36
  • At least one physicist, Dr. Guenter Nimtz of the
    University of Cologne, holds the opinion that a
    number of experiments, including those of the
    Italian group, have in fact sent information
    superluminally. But not even Dr. Nimtz believes
    that this trick would allow one to reach back in
    time. He says, in essence, that the time it takes
    to read any incoming information would fritter
    away any temporal advantage, making it impossible
    to signal back and change events in the past.

37
  • If we could send information into the past then
    we might solve the halting problem -- whenever
    the machine M halts, send a messsage back to a
    specified time t saying that it halts.
  • If at time t no message is received then one
    knows M did not halt.

38
  • Quantum entanglement. See this link and this
    link. Action at a distance.
  • Quantum computation does not lead to
    hypercomputation. But it may lead to fast
    computation.

39
Quantum Entanglement
  • At risk of oversimplification, QE is when the
    fate of two or more particles become bound
    together. A change in one entangled particle
    results in an INSTANT change in the other
    particle as well, no matter how far away it is -
    even at the opposite end of the universe.

40
Quantum Entanglement
  • In the 1970s, physicist Alan Aspect successfully
    ran a version of the EPR experiment stretched
    across a space the size of a basketball court and
    showed that quantum entanglement in fact does
    exist. With this one experiment, the possibility
    of building a quantum computer seized the
    imagination of physicists.

41
Quantum Entanglement
  • A computer based on quantum entanglement would
    have no limits at all on how fast it could
    perform logical switching operations since it
    would use "spooky action at a distance" instead
    of electrons or light.

42
Quantum Entanglement
  • A team gathered two clouds of cesium gas, each
    containing about a trillion atoms, into separate,
    sealed vessels. They then shined a laser through
    both clouds. For a split second, the clouds
    became entangled, and magnetic changes in one
    instantly affected the other. The previous
    entanglement record was a mere four atoms.

43
  • The development could lead to the creation of
    computers and communications networks that
    operate much faster than anything that's
    available today, says Peter Handel, a physics
    professor at the University of Missouri in St.
    Louis. "Information encoded in photons could be
    transmitted to places without sending them across
    space," he says.

44
  • Quantum entanglement could also allow matter to
    be transported from one location to another by
    instantly duplicating the properties of one
    object in another place. Other researchers,
    however, are skeptical about quantum
    entanglement's sci-fi aspects. "You can't
    transfer information faster than the speed of
    light, that's an immutable law of physics," warns
    Randall Hulet, a physics and astronomy professor
    at Rice University in Houston.

45
Quantum Computation
  • In a quantum computer, the fundamental unit of
    information (called a quantum bit or qubit), is
    not binary but rather more quaternary in nature.
    This qubit property arises as a direct
    consequence of its adherence to the laws of
    quantum mechanics which differ radically from the
    laws of classical physics.

46
Quantum Computation
  • A qubit can exist not only in a state
    corresponding to the logical state 0 or 1 as in a
    classical bit, but also in states corresponding
    to a blend or superposition of these classical
    states. In other words, a qubit can exist as a
    zero, a one, or simultaneously as both 0 and 1,
    with a numerical coefficient representing the
    probability for each state.

47
  • For example, a system of 500 qubits, which is
    impossible to simulate classically, represents a
    quantum superposition of as many as 2500 states.
    Any quantum operation on that system --a
    particular pulse of radio waves, for instance,
    whose action might be to execute a controlled-NOT
    operation on the 100th and 101st qubits-- would
    simultaneously operate on all 2500 states.

48
  • Hence with one fell swoop, one tick of the
    computer clock, a quantum operation could compute
    not just on one machine state, as serial
    computers do, but on 2500 machine states at once!
    Eventually, however, observing the system would
    cause it to collapse into a single quantum state
    corresponding to a single answer, a single list
    of 500 1's and 0's, as dictated by the
    measurement axiom of quantum mechanics.

49
  • The reason this is an exciting result is because
    this answer, derived from the massive quantum
    parallelism achieved through superposition, is
    the equivalent of performing the same operation
    on a classical super computer with 10150
    separate processors (which is of course
    impossible)!!

50
  • Peter Shor, a research and computer scientist at
    ATT's Bell Laboratories in New Jersey, provided
    such an application of quantum computers by
    devising the first quantum computer algorithm.
    Shor's algorithm harnesses the power of quantum
    superposition to rapidly factor very large
    numbers (on the order 10200 digits and greater)
    in a matter of seconds.
  • But large quantum computers have not yet been
    built and may be very hard to make.

51
Conclusion
  • With so much strangeness in the world, and much
    of it even having practical applications, who
    knows whether a computing device more powerful
    than Turing machines is possible?
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