Publication record · 18.cifr/1997.shor.quantum-factoring

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

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Peter W. Shor (AT&T Research)

RAI18.cifr/1997.shor.quantum-factoring

SIAM Journal on Computing· 1997· doi:10.1137/S0097539795293172

A digital computer is generally believed to be an efficient universal computing device; that is, it is believed to be 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 that are generally thought to be hard on classical computers and that 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.

quantum computingprime factorizationdiscrete logarithmquantum Fourier transformperiod findingcryptography

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Integer factorization of an n-bit number requires exp(O(n^(1/3))) time under the best classical algorithms, underpinning the security of RSA. Before this paper no polynomial-time algorithm existed on any standard computational model. Shor's quantum algorithm breaks that barrier.

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Shor demonstrated that prime factorization and discrete logarithm can be solved in polynomial time O((log N)^3) on a quantum computer via quantum Fourier transform period-finding. This was the first polynomial-time algorithm for a problem believed to require exponential classical time, directly threatening RSA and Diffie-Hellman cryptosystems.

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