Analogue algorithm for parallel factorization of an exponential number of large integers: I - theoretical description

Vincenzo Tamma

doi:10.1007/s11128-015-1190-y

Analogue algorithm for parallel factorization of an exponential number of large integers: I - theoretical description

Vincenzo Tamma

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Abstract

We describe a novel analogue algorithm that allows the simultaneous factorization of an exponential number of large integers with a polynomial number of experimental runs. It is the interference-induced periodicity of “factoring” interferograms measured at the output of an analogue computer that allows the selection of the factors of each integer. At the present stage, the algorithm manifests an exponential scaling which may be overcome by an extension of this method to correlated qubits emerging from n-order quantum correlations measurements. We describe the conditions for a generic physical system to compute such an analogue algorithm. A particular example given by an “optical computer” based on optical interference will be addressed in the second paper of this series (Tamma in Quantum Inf Process 11128:1189, 2015).

Original language	English
Pages (from-to)	5259-5280
Journal	Quantum Information Processing
Volume	15
Issue number	12
Early online date	23 Nov 2015
DOIs	https://doi.org/10.1007/s11128-015-1190-y
Publication status	Published - 1 Dec 2016

Keywords

Quantum computation
Interference
Algorithms
Analogue computers
Factorization
Exponential sums
Gauss sums

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10.1007/s11128-015-1190-y

Analogue algorithm for parallel factorization I
The final publication is available at Springer via http://dx.doi.org/10.1007/s11128-015-1190-y.
Accepted author manuscript (Post-print), 1.75 MB

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abstract = "We describe a novel analogue algorithm that allows the simultaneous factorization of an exponential number of large integers with a polynomial number of experimental runs. It is the interference-induced periodicity of “factoring” interferograms measured at the output of an analogue computer that allows the selection of the factors of each integer. At the present stage, the algorithm manifests an exponential scaling which may be overcome by an extension of this method to correlated qubits emerging from n-order quantum correlations measurements. We describe the conditions for a generic physical system to compute such an analogue algorithm. A particular example given by an “optical computer” based on optical interference will be addressed in the second paper of this series (Tamma in Quantum Inf Process 11128:1189, 2015).",

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AB - We describe a novel analogue algorithm that allows the simultaneous factorization of an exponential number of large integers with a polynomial number of experimental runs. It is the interference-induced periodicity of “factoring” interferograms measured at the output of an analogue computer that allows the selection of the factors of each integer. At the present stage, the algorithm manifests an exponential scaling which may be overcome by an extension of this method to correlated qubits emerging from n-order quantum correlations measurements. We describe the conditions for a generic physical system to compute such an analogue algorithm. A particular example given by an “optical computer” based on optical interference will be addressed in the second paper of this series (Tamma in Quantum Inf Process 11128:1189, 2015).

KW - Quantum computation

KW - Interference

KW - Algorithms

KW - Analogue computers

KW - Factorization

KW - Exponential sums

KW - Gauss sums

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EP - 5280

JO - Quantum Information Processing

JF - Quantum Information Processing

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ER -

Analogue algorithm for parallel factorization of an exponential number of large integers: I - theoretical description

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Keywords

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