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ACAT2005_Severyanov
... Using ideas published in [1] we have written a C# program tool enabling us to assemble an arbitrary quantum circuit in a particular gate basis and to construct the corresponding set of polynomial equations over Z2. The number of solutions of the set defines the matrix elements of the circuit and th ...
... Using ideas published in [1] we have written a C# program tool enabling us to assemble an arbitrary quantum circuit in a particular gate basis and to construct the corresponding set of polynomial equations over Z2. The number of solutions of the set defines the matrix elements of the circuit and th ...
Quantum Algorithms and Cryptography
... • … we could equip our laptops with tiny time machines*? • … we could travel near the speed of light (time dilation)? • … we could control quantum states? ...
... • … we could equip our laptops with tiny time machines*? • … we could travel near the speed of light (time dilation)? • … we could control quantum states? ...
ppt
... Scaling of the correlation amplitude with 1/N and t2 approximately verified However correlation amplitude is too small by 40 % ...
... Scaling of the correlation amplitude with 1/N and t2 approximately verified However correlation amplitude is too small by 40 % ...
Quantum Physics 2005
... pattern is observed when x-rays of many wavelengths are incident on a crystal and diffraction can therefore occur from many planes simultaneously. …pretty ...
... pattern is observed when x-rays of many wavelengths are incident on a crystal and diffraction can therefore occur from many planes simultaneously. …pretty ...
QUANTUM COMPUTATION Janusz Adamowski
... (2) The Bell states are the entangled states = e-bits. (3) Einstein-Podolsky-Rosen (EPR) paradox: When measuring one qubit we obtain, without performing the measurement, the value of the second qubit. Comment on property (3) Let us consider the system AB in state ...
... (2) The Bell states are the entangled states = e-bits. (3) Einstein-Podolsky-Rosen (EPR) paradox: When measuring one qubit we obtain, without performing the measurement, the value of the second qubit. Comment on property (3) Let us consider the system AB in state ...
1 - the David R. Cheriton School of Computer Science
... [Shor ’94]: polynomial-time algorithm for factoring integers on a quantum computer This could be used to break most of the existing public-key cryptosystems, including RSA, and elliptic curve crypto [Bennett, Brassard ’84]: provably secure codes with short keys ...
... [Shor ’94]: polynomial-time algorithm for factoring integers on a quantum computer This could be used to break most of the existing public-key cryptosystems, including RSA, and elliptic curve crypto [Bennett, Brassard ’84]: provably secure codes with short keys ...
Quantum computation and cryptography: an overview
... each of them with magnetic fields HA and HB ; which can be oriented in the directions: :,? and %; &; respectively, like in the Stern-Gerlach experiment for silver atoms. From the result RA of the electron’s (E) spin in the Alice’s measurement (which can result in: either parallel j "ie or antiparall ...
... each of them with magnetic fields HA and HB ; which can be oriented in the directions: :,? and %; &; respectively, like in the Stern-Gerlach experiment for silver atoms. From the result RA of the electron’s (E) spin in the Alice’s measurement (which can result in: either parallel j "ie or antiparall ...
2 - arXiv
... standard approach of [2]. In [6] the so-called Schrieffer-Wolff formalism is generalized to Lindbladian dynamics; its basic form requires inversion of the nominal dynamics operator, which is not too practical and which we circumvent here for the derivation of the reduced slow master equation (15). T ...
... standard approach of [2]. In [6] the so-called Schrieffer-Wolff formalism is generalized to Lindbladian dynamics; its basic form requires inversion of the nominal dynamics operator, which is not too practical and which we circumvent here for the derivation of the reduced slow master equation (15). T ...
Module Guide
... The course develops a two-strand approach to Quantum Computing, with an underlying mathematical strand delivered by the School of Computer Science and a quantum information processing strand delivered by both the School of Physics, Astronomy and Mathematics and the School of Computer Science. Commen ...
... The course develops a two-strand approach to Quantum Computing, with an underlying mathematical strand delivered by the School of Computer Science and a quantum information processing strand delivered by both the School of Physics, Astronomy and Mathematics and the School of Computer Science. Commen ...
Slide 1
... Eve can perform a spin measurement on “1”. However, she fails to uncover information about the state “2”: When Bob does NOT receive particle “1”, Alice performs the following operations to recover the state to be teleported: Alice makes a spin measurement on her particle “a” in the basis Then she ma ...
... Eve can perform a spin measurement on “1”. However, she fails to uncover information about the state “2”: When Bob does NOT receive particle “1”, Alice performs the following operations to recover the state to be teleported: Alice makes a spin measurement on her particle “a” in the basis Then she ma ...
here - Nick Papanikolaou
... quantum gates (X, Y, Z, H, CNOT) quantum circuits (swapping, no-cloning problem) teleportation quantum parallelism and Deutsch’s algorithm ...
... quantum gates (X, Y, Z, H, CNOT) quantum circuits (swapping, no-cloning problem) teleportation quantum parallelism and Deutsch’s algorithm ...
Quantum Computation and Quantum Information – Lecture 3
... quantum gates (X, Y, Z, H, CNOT) quantum circuits (swapping, no-cloning problem) teleportation quantum parallelism and Deutsch’s algorithm ...
... quantum gates (X, Y, Z, H, CNOT) quantum circuits (swapping, no-cloning problem) teleportation quantum parallelism and Deutsch’s algorithm ...
Powerpoint format
... Other Examples of Quantum Phenomena Spin of an electron: spin up or spin down Can be set to a continuum of values but collapses to up or down when measured with a magnetic field Polarization of a photon: horizontal or vertical Measured using a calcite crystal; can be set to a continuum of v ...
... Other Examples of Quantum Phenomena Spin of an electron: spin up or spin down Can be set to a continuum of values but collapses to up or down when measured with a magnetic field Polarization of a photon: horizontal or vertical Measured using a calcite crystal; can be set to a continuum of v ...