Peter W. Shor scite author profile

A digital computer is generally believed to be an efficient universal computing device; that is, it is believed able to simulate any physical computing device with an increase in computation time by at most a polynomial factor. This may not be true when quantum mechanics is taken into consideration. This paper considers factoring integers and finding discrete logarithms, two problems which are generally thought to be hard on a classical computer and which have been used as the basis of several proposed cryptosystems. Efficient randomized algorithms are given for these two problems on a hypothetical quantum computer. These algorithms take a number of steps polynomial in the input size, e.g., the number of digits of the integer to be factored.

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Scheme for reducing decoherence in quantum computer memory

Shor

1995

Phys. Rev. A

3,849

3,650

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Taming decoherence is essential in realizing quantum computation and quantum communication. Here we experimentally demonstrate that decoherence due to amplitude damping can be suppressed by exploiting quantum measurement reversal in which a weak measurement and the reversing measurement are introduced before and after the decoherence channel, respectively. We have also investigated the trade-off relation between the degree of decoherence suppression and the channel transmittance. Experimental verification of the commutation relation for Pauli spin operators using single-photon quantum interference," Phys. Lett. A 374, 4393-4396 (2010).

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Algorithms for quantum computation: discrete logarithms and factoring

Shor

5,584

3,497

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Elementary gates for quantum computation

et al. 1995

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We show that a set of gates that consists of all one-bit quantum gates (U(2)) and the two-bit exclusive-or gate (that maps Boolean values $(x,y)$ to $(x,x \oplus y)$) is universal in the sense that all unitary operations on arbitrarily many bits $n$ (U($2^n$)) can be expressed as compositions of these gates. We investigate the number of the above gates required to implement other gates, such as generalized Deutsch-Toffoli gates, that apply a specific U(2) transformation to one input bit if and only if the logical AND of all remaining input bits is satisfied. These gates play a central role in many proposed constructions of quantum computational networks. We derive upper and lower bounds on the exact number of elementary gates required to build up a variety of two-and three-bit quantum gates, the asymptotic number required for $n$-bit Deutsch-Toffoli gates, and make some observations about the number required for arbitrary $n$-bit unitary operations.Comment: 31 pages, plain latex, no separate figures, submitted to Phys. Rev. A. Related information on http://vesta.physics.ucla.edu:7777

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Good quantum error-correcting codes exist

1996

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A quantum error-correcting code is defined to be a unitary mapping (encoding) of k qubits (2-state quantum systems) into a subspace of the quantum state space of n qubits such that if any t of the qubits undergo arbitrary decoherence, not necessarily independently, the resulting n qubits can be used to faithfully reconstruct the original quantum state of the k encoded qubits. Quantum error-correcting codes are shown to exist with asymptotic rate k/n = 1 − 2H 2 (2t/n) where H 2 (p) is the binary entropy function −p log 2 p − (1 − p) log 2 (1 − p). Upper bounds on this asymptotic rate are given.

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Peter W. Shor

Polynomial-Time Algorithms for Prime Factorization and Discrete Logarithms on a Quantum Computer

Scheme for reducing decoherence in quantum computer memory

Algorithms for quantum computation: discrete logarithms and factoring

Elementary gates for quantum computation

Good quantum error-correcting codes exist

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