Parallel "paths" in quantum computing
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Philip Thrift
Aug 7, 2019, 4:08:50 AM8/7/19
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On Tuesday, August 6, 2019 at 5:29:04 PM UTC-5, Brent wrote:
On 8/6/2019 11:25 AM, Philip Thrift wrote:
On Tuesday, August 6, 2019 at 1:00:23 PM UTC-5, Brent wrote:On 8/6/2019 6:38 AM, Bruno Marchal wrote:If the QC does its task effectively, the output basis qbits will be put into definite states,Relatively to the observer, but in the global state, the observer will inherit the superposition state, by linearity of the tensor products and of the evolution.
In something like Shor's algorithm there is only one final state with non-vanishing probability. Yet this is the kind of algorithm that Deutsch cites as proving there must be many worlds.
BrentThat there is a multiplicity of somethingsis the basis for all semantics of quantum computing (by computer scientists) that I have ever seen.
Same for classical computation...there are lots of states or functions. Did anyone think there had to be multiple worlds for the computer to work?
Brent
There is classical parallel hardware, e.g. made with multiple processors.
Parallelism in quantum computers is achieved by parallel "worlds" or "paths":
Quantum Path Computing
Quantum circuit dynamics via path integrals: Is there a classical action for discrete-time paths?
A “problem of time” in the multiplicative scheme for the n-site hopper
Fay Dowker, Vojtˇech Havlicek, Cyprian Lewandowski, and
Henry Wilkes
"Quantum Measure Theory (QMT*) is an approach to quantum mechanics,
based on the path integral, in which quantum theory is conceived of as a generalized stochastic process."
The sum-over-histories formulation of quantum computing
@philipthrift
Brent Meeker
Aug 7, 2019, 2:03:44 PM8/7/19
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On 8/7/2019 1:08 AM, Philip Thrift
wrote:
On Tuesday, August 6, 2019 at 5:29:04 PM UTC-5, Brent wrote:
On 8/6/2019 11:25 AM, Philip Thrift wrote:
On Tuesday, August 6, 2019 at 1:00:23 PM UTC-5, Brent wrote:
On 8/6/2019 6:38 AM, Bruno Marchal wrote:
If the QC does its task effectively, the output basis qbits will be put into definite states,
Relatively to the observer, but in the global state, the observer will inherit the superposition state, by linearity of the tensor products and of the evolution.
In something like Shor's algorithm there is only one final state with non-vanishing probability. Yet this is the kind of algorithm that Deutsch cites as proving there must be many worlds.
Brent
That there is a multiplicity of somethings
is the basis for all semantics of quantum computing (by computer scientists) that I have ever seen.
Same for classical computation...there are lots of states or functions. Did anyone think there had to be multiple worlds for the computer to work?
Brent
There is classical parallel hardware, e.g. made with multiple processors.
Parallelism in quantum computers is achieved by parallel "worlds" or "paths":
Quantum Path Computing
Quantum circuit dynamics via path integrals: Is there a classical action for discrete-time paths?
But as you note with scare quotes, calling those "worlds" or
"paths" is just metaphorical. They are not worlds you can visit or
paths you can take. They are aspects of mathematical abstractions.
Brent
Brent
A “problem of time” in the multiplicative scheme for the n-site hopperFay Dowker, Vojtˇech Havlicek, Cyprian Lewandowski, andHenry Wilkes"Quantum Measure Theory (QMT*) is an approach to quantum mechanics,based on the path integral, in which quantum theory is conceived of as a generalized stochastic process."
The sum-over-histories formulation of quantum computing
@philipthrift
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Philip Thrift
Aug 7, 2019, 2:15:56 PM8/7/19
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If a multiplicity of somethings isn't present in a quantum computer, then how does the speedup occur?
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Brent Meeker
Aug 7, 2019, 3:59:04 PM8/7/19
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By not decohering at every bit flip and keeping the single state
rotating.
Brent
Brent
Philip Thrift
Aug 7, 2019, 5:56:51 PM8/7/19
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Then how does an answer come out?
Like in the solution here: https://arxiv.org/abs/1709.00735
QPC solves specific instances of simultaneous Diophantine approximation problem (NP-hard) as an important application.
QPC does not explicitly require exponential complexity of resources by combining tensor product space of path histories inherently existing in the physical set-up and path integrals naturally including histories.
@philipthrift
Lawrence Crowell
Aug 7, 2019, 7:40:51 PM8/7/19
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On Wednesday, August 7, 2019 at 4:56:51 PM UTC-5, Philip Thrift wrote:
Then how does an answer come out?
By LOCC = local operation and classical communication Largely this is a Hadamard gate for selection and a classical signal on the ancillary states.
LC
Brent Meeker
Aug 7, 2019, 10:19:57 PM8/7/19
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By decoherence at the end.
Like in the solution here: https://arxiv.org/abs/1709.00735
QPC solves specific instances of simultaneous Diophantine approximation problem (NP-hard) as an important application.
QPC does not explicitly require exponential complexity of resources by combining tensor product space of path histories inherently existing in the physical set-up and path integrals naturally including histories.
Interesting, but looks more aspirational than proven. It reminds me
of attempts to solve NP-hard problems using some analog schemes.
Brent
Brent
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Philip Thrift
Aug 8, 2019, 2:14:26 AM8/8/19
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On Wednesday, August 7, 2019 at 9:19:57 PM UTC-5, Brent wrote:
On 8/7/2019 2:56 PM, Philip Thrift wrote:
On Wednesday, August 7, 2019 at 2:59:04 PM UTC-5, Brent wrote:
On 8/7/2019 11:15 AM, Philip Thrift wrote:
If a multiplicity of somethings isn't present in a quantum computer, then how does the speedup occur?
By not decohering at every bit flip and keeping the single state rotating.
Brent
Then how does an answer come out?
By decoherence at the end.
Brent
Well, sure. But there is still a multiplicity of somethings.
Histories.
In QMT a system is defined by a triple (Ω, A, D) where Ω is the set of
histories, A is the event algebra and D is the decoherence functional. An event is a set of histories and the event algebra is the set of all events to which the theory assigns a measure. The event algebra is, then, a subset of the power set of Ω.
The decoherence functional is a function with two arguments D : A × A → C such that
• D(A, B) = D(B, A)
∗ ∀ A, B ∈ A ;
• For any finite collection of events A1, . . . , Am ∈ A, the m × m matrix
Mab := D(Aa, Ab) is positive semi-definite ;
• D(Ω, Ω) = 1 ;
• D(A ∪ B, C) = D(A, C) + D(B, C) ∀ A, B, C ∈ A such that A ∩ B = ∅ .
The quantum measure, µ(E), of an event E ∈ A is given by the diagonal of the decoherence functional D:
µ(E) := D(E, E).
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